THE OCEAN AS THE OPERATING ENVIRONMENT OF THE NAVY

Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 el a NES 'Ts /r. a) -CON-H-REN-TtA-t- L., ? A symposium ONR-3 THE OCEAN AS THE OPERATING ENVIRONMENT OF THE NAVY 50X1 -HUM Office of Naval Research Department of the Navy Washington. D.C. 124 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: CIA-RDP81-01043R002200220009-0 CONFIDENTIAL SECURITY , This document contains information affecting the national defense of the United States withinthe mean- ing of the Espionage Laws, Title 18, U.S.C., Sections 793 and 794. The transmission or the revelation of its contents in any manner to an unauthorized person is prohibited by law. Reproduction of this document in any form by other than activities of the National Military Estab- lishment and the Atomic Energy Commission is not authorized unless specifically approved by the Secre- tary of the Navy. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 50X1-HUM Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL ONR-3 ?THE OCEAN AS THE OPERATING ENVIRONME,NT OF THE NAVY A Symposium sponsored by The Office of Naval Research March 11, 12, and 13, 1958 San Diego, California 50X1 -HUM ? Oftice of Naval Research Department of the Navy Washington, D.C. 0 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 ? ? Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 3 0 0 Statements and opinions contained herein are those of the authors and are not to be construed as official or reflecting the views of the Navy Department or of the naval service at large. ? ? ? ? 'ASTIA Reference Number AD I 57 I 59 0 0 ? 0 ? ? ? ? ? r ? UNCLASSIFIED PREFACE It is becoming more and more evident that full exchange of ideas and rapid communication of results are among the most powerful stimuli, for scientific progress. The Office pf Naval Research is, therefore, sponsoring Navy-wide symposia on various subjects in order tp pro- vide opportunities for scientific personnel of Navy laboratories and contractors to get togeth- er and to discuss problems of mutual interest. In view of the increasing importance of under- water operations, the gene r al theme of this symposium is particularly timely. The program has been so arranged as to present the view- points of tile scientist, the engineeT, and the fleet officer, and I am certain that the personal contacts resulting from this meeting will plant the seeds for greater progress of the NewNavy. 4?1:191...X.1?191???????????????? Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 R. BENNETT Rear Admiral, USN Chief of Naval Research 111 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 MEMBERS OF THE SYMPOSIUM PROGRAM COMMITIU Chief of Naval Operations - Captain R. H. Holden, USN Commander C. L. Scherrer, USN Bureau of Aeronautics - Mr. F. W. S. Locke . Mr. I. H. Gatzke Bureau or Medicine and Surgery - Captain J. R. Kingston, MC, USN Bureau of Naval Personnel 7 Commander E. G. Fitz-Patrick, USN Bureau of Ordnance - Dr. E. S. Lamar Dr. S. Skolnik Bureau of Ships - Mr. R. W. Stewart Mr. W. B. White Mr. L. M. Treitel Bureau of Suppliei and Accounts - Mr. T. Seery Bureau of Yards and Docks - Mr. S. Rockefeller Marine Corps - Dr. C. E.. Wise, Jr. 'Office of Naval Research - Dr. J. N. Adkins ' Dr. I. Estermann, Chairman iv - ?77???=ncar,r47,,, ? CONTENTS Preface OPENING REMARKS I. Estermann, Office of Naval Research WELCOMING ADDRESS CAPT J. M. Phelps, USN, Navy Electronics Laboratory THE OCEAN VIEWED AS A MILITARY ENVIRONMENT RADM R. Bennett, USN, Chief of Naval Research THE SCIENTIFIC PROBLEMS OF NAVAL OPERATIONS RADM J. T. Hayward, USN, Assistant Chief of Naval Operations for Research and Development MARINE CORPS OPERATIONS Brigadier General S. R. Shaw, Deputy Chief of Staff, Research and Development, USMC THE ORGANISATION OF BRITISH NAVAL RESEARCH AND DEVELOPMENT R. V. Alred, British Joint Services Mission THE CANADIAN PROGRAM IN UNDERWATER RESEARCH J. J. Green, Canadian Joint Staff AN ADDRESS L. A. DuBridge, President, California Institute .of Technology A SURVEY OF HYDROBIOLOGICAL ASPECTS OF NAVAL OPERATIONS S. R. Galler, Office of Naval Research DEEP MOORED INSTRUMENT STATIONS J. D. Isaacs, Scripps Institution of Oceanography *Published in SECRET Supplement in 1 3 5 8 14 21 27 35 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 RESEARCH PROBLEMS OF SUBMARINE OPERATIONS UNDER-ICE IN THE ARCTIC OCEAN W. K. Lyon, Navy Electronics Laboratory ,REQUIREMENTS. IN MILITARY OCEANOGRAPHY J. Lyman, U.S. Navy Hydrographic Office MAN AND THE UNDERSEA ENVIRONMENT L. G. Goff, Office of Naval Research INFLUENCE OF THE OCEANOGRAPHIC ENVIRONMENT ON UNDERWATER DETECTION E. C. LaFond, Navy Electronics Laboratory ACOUSTIC- PROPERTIES OF THE OCEAN BOTTOM ' J. E. Nafe, J. L. Worzel, and M. Ewing, Lamont Geological Observatory MICROSTRUCTURE OF THE OCEAN AS IT, RELATES TO THE TRANSMISSION OF UNDERWATER SOUND D. S. Potter, Applied Physics Laboratory, - University of Washington THE PAST, PRESENT, AND FUTURE OF UNDERWATER CLASSIFICATION A. J. Hiller, Naval Research Laboratory 42 52 61 71 107 126 THE CLASSIFICATION OF UNDERWATER TARGETS BY ACOUSTIC METHODS D. A. Wilson, Navy Electronics Laboratory AN OPTIMIZATION PROGRAM FOR INSERVICE WEAPON SYSTEMS LCDR R. L. Ploss, USN, Office ,of Naval Research 137 162 DISPOSITION OF RADIOACTIVE MATERIAL IN THE OCEAN C. L. Newcombe, Naval Radiological Defense Laboratory 174 RESEARCH TRENDS ? IN MARINE PROPULSION ,CAPT W. T. Sayer, USN, Office of Naval Research NUCLEAR CLOSED CYCLE GAS TURBINE 195 POWER PLANT STUDY S. T. Robinson, Sanderson and Porter HUMAN 'LIMITATIONS IN NUCLEAR PROPULSION CAPT J. A. Brimson, MC, USN, Bureau, of Medicine and Surgery , *Published in SECRET 'Supplement 1-Manuscript not alA.ilable vi 211 ? I. ? POSSIBILITIES FOR REDUCING SHIP MOTIONS AT SEA E. V. Lewis, Stevens Institute of Technology SOME RECENT RESULTS IN WATER-ENTRY MODELING J. G. Waugh, Naval Ordnance Test Station JULIE AND GILDA 218 242 CDR B. J. Jones, USN, and LCDR C. E. Rogers, USN, Antisubmarine Defense Force, Atlantic Fleet THE EFFECT OF SOUND VELOCITY GRADIENTS ON THE DAMAGE RANGES FOR AN UNDERWATER EXPLOSION E. A. Christian, Naval Ordnance Laboratory "PROJECT MONTE" A. :R. Focke, Mine Advisory Committee OFFENSIVE SEA MINES A. H. Sellman, Bureau of Ordnance, Navy FUTURE MINE DEFENSE CAPABILITIES RELATED TO THE OCEAN AS THE OPERATING ENVIRONMENT H. A. Johnson, Navy Mine Defense Laboratory AMBIENT NOISE, ITS ORIGIN AND CHARACTERISTICS R. A. Frosch and A. Berman, Hudson Laboratories SOUND PROPAGATION MEASUREMENTS J. B. Hersey, Woods Hole Oceanographic Institution TOXICOLOGICAL AND HEALTH HAZARDS OF GUIDED MISSILES LCDR H. D. Baldridge, MSC, USN, Naval Medical Research Institute *Published in SECRET Supplement vii 302 315 334 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 CIA-RDP81-01043R002200220009-0 flIsifid in Part SanitizedC s, UNCLASSIFIED ?????????????????????????????11.10. OPENING REMARKS I. Estermann Symposium Chairman Office of Naval Research When we began to organize this symposium in the pre- Sputnik era, two questions were frequently asked. First, what is the value of such a symposium, and secondly, what is its purpose. The answer to the first question has been given already by your presence here - frankly, we did not expect such a wide audience, and it is a particular pleasure for me to bid you a cordial welcome. I hope that when you leave, you will have no doubts left about the value of this symposium. The second question is more difficult to answer. As you know, there is an abundance of scientific meetings, and it may well be questioned whether the organization of an additional one really serves a worthwhile purpose. Let me say that we in ONR do not con- sider these Navy-wide scientific symposia to be in competition with other meetings. In our opinion, they have a peculiar function which no presently existing type of meeting can fulfill This function is intimately connected with the position of the scientist In the Navy and with his interaction with other parts of the Navy. Every member of an organization has the obvious duty to contribute to the mission ,of his organization. The scientist, however, has the additional duty to further the mission of science. While in the first respect his superiors are the proper judges of accomplishment, in the second respect, judgment can be exercised only by his peers. .In the Univ- ersity environment, this opportunity is provided for by standard scientific jourhals and meetings of professional societies, plus a number of ad hoc conferences on specific. subjects. The Navy scien- tist, however, can utilize this procedure only to a very limited extent. In the first place, he is usually more or less isolated from those in the Navy who have the responsibility for its perform- ' UNCLASSIFIED Approved for Release 2013/08/02 CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Cop Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Estermann UNCLASSIFIED ance, namely the leaders of the operating fleet. Secondly, his work is to &large extent classified ane cannot be presented for judgment to the scientific community at large. It is therefore necessary to provide the opportunity to present it tea selected group of scien- tific peers -- and this is one of the reasons why we are aswmbled here. To break down the isolation, we have invited key people from the operating fleet and from the Material Bureaus -- the ultimate consumers of the Navy scientist's work. I am happy to see this group so. well represented here today, and I hope that this symposium and those following it will help in establishinE a closer bond be- tween the scientist, the Bureau engineer, and the fleet officer, who after all are all members of the same team. The program has been so arranged as to give the scientists a forum for his advanced thinking, and to the others, a chance to present their current day- to-day problems for the scientists' consideration. We are sincere in our conviction that this interchange will contribute a lot to the future of the Navy Scientist and the Navy as a whole. ? ? ? ? ' ? ? ? ? ? 2 ? ? UNCLASSIFIED acl UNCLASSIFIED WELCOMING ADDRESS ? Captain J. M. Phelps, USN W. S. Navy Electronics Laboratory San Diego, California ? Good morning, Admiral Bennett, ladies and gentlemen.... We at NEL are indeed happy to have you here with us today and we o welcome you to the Laboratory to take part in this Symposium on Basic and Applied Science. You as a group represent a very selected combination of industrial, educational and governmental civilian and military professional competence that is assembled here to concentrate for several days on some of the basic problems affecting the Navy in its natural environment, the sea. We cannot begin to over-esti- mate or to measure the long term benefits to be gained by this very act of your taking time out to come here and to reflect and think about and concentrate on some of these fundamental issues that are going to be discussed within the next few days. I hope that you will be stimulated and that you will gain some fresh points of view and insight into what the other fgllow sitting ,alongside you or in this auditorium is thinking about and peAbaps you can get a little new perspective on some o:.the prob- lems you face .from day to day. I think it is important that every once in a' while we take the time 'out to do this. I think we have many solutions to our problems that are available. They are float- ing around some place and we concentrate on some of the details and forget many times to take ourselves outside of this overall probleth and look at it with this broad point of view. I, think that this sort of a meeting does enable us to do that. Now too often we just- ify meetings such as this on the basis of cross-fertilization of ideas, but I recommend that you forget for a moment this cross- Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 3 UNCLASSIFIED ? Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 ? ? ? Phelps UNCLASSIFIED fertilization and look beyond your present horizons for new ideas. What we need today are not just new ideas on what we already know ? about. We need some real inspirations to solve our problems. Suc- cess, so they say, is supposed to come to those who are actually prepared for it, and this type of a meeting helps us to get pre- pared; and I hope that this particular one, sponsored by the Office of Naval Research, will. help all of us prepare ourselves to make better contributions to the overall Navy's efforts. So to each one of you I hope you thoroughly enjoy your stay at NEL, and during the few times you have outside of the Laboratory itself when these sessions are over, I.hope you enjoy your stay in San Diego. ? ? ? ? ? ? ? ? - UNCLASSIFIED UNCLASSIFIED THE OCEAN VIEWED AS A MILITARY ENVIRONMENT Rear Admiral Rawson Bennett, USN Chief of Naval Research The mastery of the sea has traditionally been the basic problem of the Navy. In successfully designing, building and oper- ating a powerful modern Fleet both on the surface of the ocean and in the depths beneath, much depends on how well we understand the environment of the sea itself. Consequently it is most appropriate that the first specialized annual Navy science symposium should deal with the ocean as a military environment. When I opened the first annual symposium a year ago in Washington, I noted that scientists throughout the Navy laboratories are widely separated by geography and administrative boundaries. I pointed out that one of the principal benefits of this symposium is that it brings together many of you working in related problems to exchange ideas and familiarize yourselves with one another's work. Oceanography, because of the highly diverse aspects of this field, probably more than most scientific fields needs a closer drawing together of those whose work touches upon this area. For example, acoustics and bidlogy are normally unrelated but in ocean- ography they have a direct relationship. In additionl_geographyi. geology, physics, chemistry, metallurgy, and naval architecture, all. play important roles in this field. . The Office of Naval,Research has more than,a_icutine est in. the research in this field. In fact, our,obeanographic,con- tract research program represents the principal effort of the Govern- ment in 'the field of physical oceanography at private or non-go-liera- ment institutions. Through these contracts these institutions n ria ss T ed in Part - Sanitized Copy Approved for Release 2013/08/02 CIA-RDP81-01043R002200220009-0 5 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 CIA-RDP81-01043R002200220009-0 - Bennett UNCLASSIFIED receive the major portions of their research funds for this program. This has been the principal means by which the United States during the past ten years has been able to move into a field which prior to World War II was dominated by Western European scientists and in- stitutions. Recently Soviet Russia has taken the lead in the number and size of oceanographic vessels, but not in quality of research results. We have also participated in setting up the new Committee on Oceanography, through which we plan to provide a national center for focusing attention on oceanography in the United States. The Committee is supported jointly by ONR, the Atomic Energy Commissibn, and the U. S. Fish and Wildlife Service. This group is to be called upon for advice on current oceanographic problems, and, in addition, will provide counseling, planning and coordination in long range oceanographic research. For the first time there will be an established means through which the various oceanography institutions and laboratories with programs in this field may act as a unit. Individual members of the Committee have been appointed by the President of the National Academy of Science. In carrying out its work, the Committee has formed specialized standing and ad hoc panels and subcommittees with adequate staffs. One of the contributions, the Committee will make will be to provide forums for the discussion of problems of concern to all branches of oceanography -- such as manpower, ship and laboratory facilities, instrumentation, data processing and similar common interests -- and foster the research for solutions to these problems. Although the Navy is primarily interested in viewing the ocean as a military environment, it is characteristic of our re- search programs that more than just military development is bene- fited. For'exemple, our interest in amphibious operations stimu- lated us to study sea and: surf phenomena because of their vital role in the success of such operations.- This'led to giving us a better ' understanding of waves, sea and surf. We developed theories and then confirmed and: modified them by aerial mapping of the sea surface. A practical 'result of these studies was a decision by the Military Sea Transport Service to route ships in accordance with meteor- - ological and oceanographic conditions and forecasts. In a test, a ship routed in this manner arrived at a European port one and one days ahead of schedule while another ship following the custom- ary great circle route arrived one day late. Conversely work in oceanography pursued by investigators 6 UNCLASSIFIED Bennett UNCLASSIFIED with no military application or benefit in mind has proved to be of great value to us. An excellent example is the Navy's use of the Piccard bathyscaphe, the TRIESTE, for a program of deep sea research last summer. The TRIESTE was developed and built by Professor Auguste Piccard through his own interest in deep diving vehicles. Enough craft of this type could explore about 99 percent of the sea floors in the oceans of the world. The Navy plans to use the TRIESTE not only to explore the ocean environment at great depths but also to evaluate the potential- ities of the bathyscaphe both as a research tool and as a naval craft, such as a submarine rescue vessel or a deep' diving submarine. In the series of 26 dives carried out last summer off the coast of Naples the emphasis was on the study of the field of sound in the ocean growing out of the Navy's great interest in underwater a- coustics in submarine warfare. We combined investigations in bio- logy, geology, and physics of the ocean depths in an attempt to identify sources of ocean sounds and to determine the sound trans- mission qualities of the ocean and the bottom. One of the scientists who contributed so much to the suc- cess of the expedition last summer was Dr. Andreas Rechnitzer of your awn Navy Electronics Laboratory. In fact, our program for next summer calls for us to bring the bathyscaphe to San Diego for a series of dives in this area. Even though most of the dives last summer were conducted just off the romantic Isle of Capri, my people tell me that they will be happy working here in San Diego next sum- mer. I have just barely touched on the many ways that the study of the ocean has a vital relationship to naval operations. We know that the ocean affects the weather and might give us the clue to long-range forecasting, that chattering fish can be a serious hazard to sonar operations, and that we can design more efficient hulls if we know more about ocean waves. 'Most tantalizing of all is the know- ledge that the ocean contains enough. deuterium to provide virtually unlimited cheap hydrogen fusion power if we can but solve the secret of how to obtain it. Whether or not your interests are inclined toward the Navy; the ocean is an integral part of man's life. The ocean spawned the first living and growing thing and holds the key'to our future civilization.. Any new ,knowledge that can be gathered about this still mysterious environment -- as challeng-ing as is outer space --- is valuable and urgently needed. n iassf ed in Part - Sanitized Copy Approved for Release 2013/08/02 ? CIA-RDP81-01043R002200220009-0 7 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL THE SCIENTIFIC PROBLEMS OF NAVAL OPERATIONS Rear Admiral J. T. Hayward, USN Assistant Chief of Naval Operations for - Research and Development ? Admiral Burke wanted to send his regards to the Symposium and you won't object, I am sure, if I just cross off "scientific" on this talk and say "The Problems of Research and Development," because we have many of them. In the reorganization in the Chief of Naval Operations' office he has designated my office the Assistant Chief of Naval Operations for Research and Development, where we have the overall programming and direction of the research and development program for the Chief of Naval Operations. We use the very able staff of Admiral Bennett, Chief of Naval Research, to assist us to do this job. Of course we have many problems. If you look at the spectrum of war, you see what faces the Navy. We have all the way from the mega war, down to the situation that you have in Indonesia today. Now the research and development program of the Navy is to support the programmed objectives of the Navy, so this-means that our problem is far from simple. You get missiles such as the BULLPUP, which stems from a requirement for the Marines for a conventional weapon to be used in local situations where it is neces- sary. Our general philosophy in those fields, of course, is the precise delivery of weapons on military objectives. There are a lot of places and a lot of times when you don't want to incinerate the whole countryside and you have alot of friends.. Now if you look at our program, we have divided the overall research and development program into two parts. Part One, which are Weapons 8 CONFIDENTIAL ? Hayward CONFIDENTIAL Systems which lead to hardware. Part Two is the basic and applied supporting research of the Naval establishment. For your informa- tion, it runs a little bit higher in part two than it does in part one. If you look in the Part One situation as we exist today, the first thing on the priority list is the fleet ballistic missile or the POLARIS pro- gram. This. consists of-marrying a ballistic missile to a nuclear submarine. This, however, of course, just applies to the mega-war situation. I am sure most of you realize that this would be of little use to us in a situation such as Indonesia today. So we are faced with the problem of trying to keep a balanced situation. There are a lot of people who would put us all under the water and build nothing but POLARIS submarines. However, this would be very unwise. I am sure the opposition Will go down any path if we don't go down, and if they can get us to just go down the path. of general war we'll be eaten alive. Now, in the situation of the POLARIS which is coming along very well---we actually have at the moment three boats programmed. These boats, of course, have sixteen ballistic missiles in them; they have a 600 pound war head; it's a 1500-mile nautical missile. We hope, if the Inyokern boys do their job, that we can launch it sub- merged, and as you can see, it is a very potent system, and it backs the Navy philosophy that we feel that the deterrent force should be flexible across the spectrum also. You shouldn't put all your eggs in one basket, not just in missiles, not just in manned aircraft, but you need a posture such that the enemy is given great pause before he attempts to attack you in the all-out situation. And you certainly pose a problem to him with this particular weapons system. Now, naturally, after seeing this and seeing what we can do in this, it really brings the ASW picture to the forefront. There is one very important thing that has happened in ASW that most people don't seem to realize, and that is that there was a time when ASW was easy, when all that was coming was to sink you and you could always make the basic* assumption that he was going to try and sink you, and we didn't realize how easy this made the problem and, in a lot of instances he came just to sink you. Now when he comes, he is going to try and evade you and he is prob- ably going to be a lot less interested in sinking a specific ship, particularly in the threat eto our country from submarine-launched guided missiles. Admiral Burke and the Vice Chief of Naval Operations have been very cognizant of this problem. They have set up Admiral Weakley, directly under Admiral Burke, as Op-001, who has the ASW problem complete, to see if we cannot really help ourselves 9 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Hayward CONFIDENTIAL in protecting the country from this guided missile threat from sub- marines. In addition, we have to do the conventional ASW job because we are a member of a free alliance, and the free alliance exists because of the seas, and if we cannot control the seas, the free alliance will fall. So we have both tasks to do. Now, in connection with this, the second priority in our weapons systems are, of course, nuclear reactors. Most of our nuclear reactor program has gone into attack submarines to date. However, we do have the LONG BEACH and we do have a DLGN and w.e do have a CVAN.. In an attack submarine we have found in recent exercises of the SKATE versus conventional submarines in the Atlantic that it is a very potent weapon. They can really kill the conventional sub- marine practically 95 percent of the time. The SKATE's remarkable performance really gives us great hope. However, when you begin to look at the problem, talking about scientific problems, suppose we could really communicate with our submerged submarines and vector them from the surface. You always get back to the inter- surface problem. We would really have a three-dimensional hunter- killer force. As you know, today whenever we are running against enemy sub- marines, we usually always have to get rid of our own, get them out of the area, because there is no real way to communicate or to know where they are. On the East Coast they have tried some operational experiments using the UQC Equipment from a helicopter and have had real good luck keeping a submarine directly underneath one of our major ships and using it as part of the detection system. But these are not the answers obviously and we have a lot of work in the research and development field, particularly with the problems of detection, which is number one, of course. If we could just break that barrier of 4500 feet a second and get some method of detecting a submarine other than acoustic, we would be in business. Not only would we be able. to have a really effective high rate of sweep but we would certainly be able to cover tremendous areas and would be able to. detect where we cannot detect today. - One of _our ideas, of course, is to try and get the fixed wing airplane back into the picture, of the detection field. It is a pretty bad situation at the moment, as you all know. We are trying everything from dunking from fixed wing air- craft to the JULIE system, of course, and the JEZEBEL system. Now, in the problem of localization, we feel that with the JULIE coming along, we are probably pretty good, about 85 percent accord- ing to the results that we have today in this particular field. CONFIDENTIAL 10 CONFIDENTIAL Hayward ? However, one of our problems is the space we have to cover and the back-up forces required to really implement this particular prob- lem against the submarine. There has been considerable thought given to the use of mines. In other words, we would use something such as the Mark 52 or this type of mine to protect and keep submarines off the great portion of our coast. As you know, the continental shelf in ? the Atlantic gives us this particular ability. However, we are faced with the international problems of the three-mile limit and I doubt very much if we will ever, in peace time do it, We certainly don'a over- look this particular way of using mines as a defense against submarines. We are also looking into active systems, real large transducers, off the Atlantic coast, in addition, to back up the present SOSUS sys- tem, which unfortunately a lot of people think can tell the position of a submarine but really is only an alerting system at the moment. But this particular effort in ASW is the number one effort we have really in the R&D program. We are getting additional money for it, and we hope that by the additional effort that we can get some results. At the moment, of course, in Congress, where Admiral Bennett and I spend a goodpart of our time, this is a very well spoken about subject. It just seems that at long last everybody has awakened to the fact that the submarine poses a great menace not just to our ships but to the country itself. Now, of course, no words of our problems would be sufficient or long enough if we didn't swell on space. Everybody is going to the moon these days, including ARPA (I don't know if you know about ARPA, which is the Advanced Research Project Agency which is coming into being with Mr. Johnson as Director and Dr. York as his Technical Assistant). All the service programs will be submitted to these people for review and implementation. In the Navy's part in this, of course, we have submitted the follow-on to the Vanguard using the second and third stages.and another additional booster THOR, and we have also submitted the NOTS proposals on the five-and-dime satellite, as we call it. We 'havein the Navy at the moment'been designated to carry the ball as the executive agent for the satellite tracking systems that are. run by the Department of Defense. We are in the midst of discussions now with the Army, the Air Force, the National Science Foundation, and the National Academy on this particular subject. This is a tre- mendous job and is going to 'involve considerable sums of money, am sure. In addition, the Navy has been named the executive agent for the Pacific guided missile range out here at Point Mugu and South Camp Cooke, which incidentally, of course, has the only east-west launching sites, where you can launch polar ortibal satellites which ? you cannot do down in Patrick, Florida. I am sure that the program 11 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 r Hayward CONFIDENTIAL will be funded in the near fiiture and we will have a pretty live national program. The Navy's position is that we felt there should be a national program and tha4 no service itself should go off into the business of launching satellites---that it should be integrated into a national program. We had definite requirements for reconnaissance, communication, navigation . . . things of this kind that we wanted every bit as much as the other services.. Of course, there is another side of the picture which is the purely scientific picture, in which we Care naturally interested, also. ? Now in the organization business, I am interested in the British organization. It is always very funny---as a matter of fact when I took this job over when the Sputnik went up, I was greatly amazed when there was all of a sudden a great hue and cry to reorganize the Joint Chiefs of Staff. I couldn't .see the connection between the Joint Chiefs of Staff and My troubles in R&D. They had never said no to me in any way, and I was very much amazed to find out that the Supreme Court deliberated and Congress debated but the Joint Chiefs, they always bickered. It was my first introduction to this particular side of the organization. There is a great tendency in people to want to set up a monolithic structure in research and development, a centralized agency that does all of it. There is a great tendency for people to want to separate basic research from the services, which I am convinced is a very grave mistake, and the Russians as long ago as 1928 made two capitalistic decisions in this line, and the first one was to decentralize everything they could in the research and development business and they have something like 775 various institutes of R&D all doing vari- ous parts and pieces. They also let anybody who had a good idea submit designs whether they were contractors or not. Tubiloff and Sitkowski were the real people who made this decision; they convinced Stalin that this was the way to go. And I am a great believer that we should keep our research and development decentralized. We in the Navy feel that if they take the basic research away from the services, this communication which is one of the biggest problem in this business, well we would lose it. . Take the one subject we are all interested in, oceanography, in which incidentally I feel we have got to make a very much greater effort: I was quite successful thislast week in getting into the budget a -research ship. When r see the history of re.aearch ships in the Navy I am very much upset. They have tried for years and years and years and they have always fallen out. I think one of the reasons it has fallen out was that, with all due respect to the Bureau of Ships, maybe we should just have bought a ship and remodeled it rather than putting it in the regular ship building program because it was always put down at the bottom of the list. ? - ? 12 ? CONFIDENTIAL ? ? CONFIDENTIAL ? ? Hayward I can assure you that we are going to make decidedly more efforts in this field of oceanography, and we arg going to try and do the best we can in the ASW business. There has been terrific pressure on us (I don't know whether Admiral Bennett discussed it or not) to have an ASW laboratory. Well, this was fine but when you begin to think about it, I have built several in my day.. .you have air, surface, sub-surface, and you get a laboratory of about 3,000 people; as a matter of fact, it is a tremendous job. What we have come up with we are going to try and make a group on the West Coast and a group on the East Coast on this subject and, of course, the best way to do this is to get the Directors of NEL, Inyolcern, Scripps---and as a matter of fact, Admiral Burke and Dr. James R. Killian now decided we should have a uni- versity tied up with it, so we are going to get Dr. Henderson from the University of Washington, ---get these four peopld to sit down and come up with some recommended program. Of course, within this group you would have your weapons; your detection, you would have all of the ASW problems. ? The West Coast lends itself a lot easier to this praticular situation than the East Coast does. You have the services here and I hope you will be able to come up with a real proposal on this. We intend to do the same thing on the East Coast with the Hudson Labs, USNUSL, Johnsville, and on the weapons side would probably be NOL. However, they have a much greater problem than you people have out here where you are a little more centralized. I want to take this occasion to tell you that Admiral Burke is probably one of the strongets proponents of Research. and Development. You may have read all of the trouble that the other services had with the universities and the research business. One of thelirst decisions that he made was that research would be the last thing that we are going to touch. And of course, over on our side of the building (over in Admiral Burke's shop) we have the greatest and highest respect for the Office of Naval Research. We can't- say too much fdr Admiral Bennett, Dr. Killian, and hi people. They have given the Navy a very excellent and marvelous reputation in-the scientific world in the United States and also across the seas. It is why on every?occasi'on that I can, I try to tell people in the Navy that are 'assobiated with this program just what a fine job ONR is doing and that we in the Chief bf Naval Operations' office certainly know it and appreciate it. -Thank yo'u for being here. ? 13 " CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED MARINE CORPS OPERATIONS S. R. Shaw Brigadier General, U.S. Marine Corps The role of the Marine Corps is that of a national force in readi- ness. This means a force ready for instant action in any of a wide variety of circumstances and places. Because the world is mostly covered with oceans any significant force in readiness must be capable of using the oceans to get to the scene of action - and to make amphib- ious landings on a hostile shore without additional preparation. This, of course, is the Marine Corps' unique characteristic. To place Marine Corps R&D in proper context, I would like to briefly review a bit of amphibious history before we come to the pre?ent, and talk of the future. Prior to World War II, many military men had come to the conclusion that the firepower of the defense had made amphibious operations impossible. The Marine Corps and the Navy believed that this defeatist opinion could not prevail if the power of the United States was to be effective beyond our own shores. By combinations of new doctrine weapons, equipment, and techni- ques and trainini, we introduced a revolutionary strategic capability to the world. This history of World War II is a story Of an unbroken series of successful landings on hostile shores. At the close of World War II, the military pessimists once again foretold the doom of amphibious operations. The nuclear weapon was said to have given the military commander such an increase in fire- power, that no landing could be made. As it looked to them, the enormous concentration of ships and supplies of our World War II assaults was a natural target for the nuclear weapon. But these pessimists did not allow for the resources of American ingenuity. 14 UNCLASSIFIED ' Shaw UNCLASSIFIED The enormous increase in firepower which the nuclear weapon gave to the military commander was accompanied by the advent of another new device of utmost military significance. This is the VTOL aircraft as presently typified by the helicopter. It has proved to be as important an advance in tactical mobility as the nuclear weapon was in firepower. Recognizing both the threat and the promise of nuclear weapons and the capabilities of the helicopter, the Marine Corps and. Navy set to work- to develop a new amphibious concept which would give the landing force the advantage of the quantum jump of the helicopter's tactical mobility, thereby attaining an entirely new magnitude of power, speed, and flexibility: Further, the new concept would provide for maximum exploitation of nuclear firepower in the attack, while at the same time reducing the threat of nuclear cOunterattack to an acceptable degree of risk. The effect of the great increase in the tactical mobility of the landing force cannot be counted by adding it arithmetically to the great strategic mobility we already possess in our fleets. It must be measured by multiplying the two factors. The combination of the two -- the new tactical mobility we have gained, and the existing strategic mobility -- has endowed the amphibious attack with enor- mously greater impact and flexibility. This more powerful nature obtains under all conditions of nuclear or non-nuclear war. With or without nuclear weapons support, Marine air-ground landing forces, organized, trained and equipped to exploit the speed and flexibility of the helicopter, can be projected by seapower deep ashore at any point on the world littoral without regard for the nature of the shoreline, and without necessity for direct beach attack. The shorelines of the world are no longer natural defenses against our attack. Hydrography no longer confines us to a few selected beaches whose advantages the enemy can see as well as we. The effects of weather are considerably reduced. The landing forces, covered and supported by the new aerial weapons of the fleets, closely coordinating their rapid maneuver with supporting Marine and Navy aircraft from carriers, can strike an enemy's defensive .system with paralyzing strategic effect. The ultimate goal of this-concept is an all-helicopter assault which will provide maximum impact and freedom of action for the landing attack launched from the seas we control. We have not yet reached this goal. But we have made great strides. We can now " make a two-pronged attack, one prong, the vertical assault by heli- copter, deep in the hostile rear, and the other a coordinated surface 15 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Shaw UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 attack across the beaches using conventional means of reaching the shore. The latter prong is now the major effort: We are working hard toward making the helicopter assault our major effort: When this is achieved, we will then proceed to our final objective, and the helicopter assault will become the complete assault. The capabil- ities we have now, gives this country's seapower far greater effect than was displayed in those great amphibious attacks of World War II. We are on-the way to a capability which will assign to our nation's seapower an effectiveness of towering order. The development of this concept emphasizes and multiplies the basic characteristics essential, in the balanced fleet -- striking power, staying power, versatility, mobility and defensive power. So much for our major doctrinal developments. The techniques we will use will continue to emphasize hard and savage fighting. We no longer will land at the water's edge and heavily crunch our way forward. We must travel light - and fight with rapid, bold maneuver. To fit ourselves, our weapons and equipment, our techniques and training to this new method of fighting, requires many things to be done. We have accomplished a good deal already. Our developmental efforts are keyed to this goal. More must be done. Now then, where does science and research activity fit into the developmental goal of the Marine Corps. The Marine Corps employs primarily, the coordinated effort of the Navy department done by the agencies of the Office of Naval Research, and the Bureaus, to provide us with the basis for development. Secondarily we employ the resources of the other military departments. We have many of the same developmental problems that the other services do in such areas as communications and the intelligence. In addition we have some dandy-puzzlers that are peculiar to our modern doctrine for amphibious assault. Before mentioning some of these I should perhaps satisfy a ques- tion that may be in your minds as to -where do missiles fit in Marine Corps' operations. Now, as some of you know, around Washington, when you say the word missile you are supposed to have an expression on your face, in your voice which indicates great overpowering urgency. Most- of.the, time, the expression actually achieved may be described as frantic. So you can see that missiles can be classed as urgent. Fortunately, at least for the Marine Corps, we have not had to acquire the same degree of urgency as the other services. 16 UNCLASSIFIED Shaw UNCLASSIFIED The Marine Corps is not involved in those great engines of massive destruction, the intercontinental and intermediate range missiles .such as Titan and Atlas, Thor, Jupiter, and Polaris. The modern missiles the Marine Corps takes must be capable Of being landed, relatively light and compact and ready for action without prolonged preparation. We have taken those that are suitable -- an artillery type, the Army's Honest John, an anti-aircraft type, the Navy's Terrier, fired from ground equipment developed to give us the first truly mobile guided missile outfit. When the Army's Hawk anti-aircraft missile is ready, with certain special equipment for landing force use, we will add it to our weapons. Our aviators use the same air-to-air missiles as the Navy, Sidewinder and Sparrow. Now I intend to mention some areas where scientific thought, research and development can be applied to the greatest advantage in developing our combat capability. One of these is the problem of specifying military character- istics of equipment to meet temperature extremes. Here I mean ground surface equipment. As many of you know it is the general practice to specify that equipment must operate at minus 65 degrees. This causes a great deal of effort to come out with gear which can meet this extreme requirement, but only after much time and money has been spent in trying to reach that extreme. We in the Marine Corps have begun to question the wisdom of this practice. It is evident that these extremely low temperatures are only to be found in a very few, relatively small and very remote places of the world. The extreme lows in these places only occur for a relatively few days of the year. The probability that signifi- cant combat action could ever take place in these odd spots, in those few periods, seems very low indeed. Further, research in human activity indicates that no real fighting could take place in such weather. At such extreme lows, the only time a fight is likely is when you and an enemy reach for apiece of firewood at the same time. The question that we are ,asking ourselves is - is it really worthwhile to specify that standardized equipment should demand such low temperature capabilities. We believe it to be,a question that deserves serious consideration by all of us. Land mine's are like the 'old Colt 45, they are great equalizers. They are the greatest menace there is to mobile forces and swift, decisive combat. The Russians use them in great numbers. Qur past and present methods of finding them are rather primitive and usually painful. We usually blow somebody up as the first indication that Mines are present. Then we search them out and dig them up, 17 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Shaw UNCLASSIFIED one by one. We need a'means of finding them before we ever commit forces to a course of action. And then if we cannot-avoid them, -we want to get rid of them on a big scale, and fast. We don't have an answer.to this one yet. Another area where we are most anxious for early and signifi- cant development is in the power train we use in our military vehicles. Almost without exception the power trains, over the years, have become more complicated, and heavier, requiring great precision. in building - and repair - and more fuel to make them go. I will freely admit that this situation is largely of our own making in the military services. Industry has engaged in the busi- ness of developing the power train of the vehicles so that women and children simply sit behind the wheel and let the vehicle do the driv- ing. The refinements have been very enticing to the military. But as in most things enticing, there has been an additional cost. And not just the "slight additional cost" so dear to the heart of the auto- mobile salesman. The cost is measured in rivers of fuel. Fuel that has to be moved in steel ships and steel drums and vehicles - expensive in military manpower, materials and production cost. It is measured in the extra dollars paid to produce the complicated precision- built power trains. It is measured in the additional man hours for maintenance, and for handling of extra spare parts. We need today military motors and transmissions that will reverse the trend we have been following. We need to energetically pursue some of the engineering features which are already being explored. We need rugged, reliable, simple economical power train - for. our vehicles. We need them badly. I would now like to leave these big picture problems that appeal to Pentagon types and to big industry and turn to a couple of problems that we feel are every bit as important. In an era when a project has to cost a hundred million dollars or more to be recognized as impor- tant, these have the misfortune to be in the pocket change category. They are of the utmost importance to us, however, because they relate to the welfare and combat effectiveness of the individual Marine - who is the greatest asset the Marine Collis has. 18 UNCLASSIFIED Shaw UNCLASSIFIED The new methods of fighting will place a premium on the indivi- dual's capacity to fight in small units - and to endure the loneliness and privation of the battlefield. It will mean much to us to increase the individual Marine's confidence - and to reduce his possibility of becoming a casualty. It is here that one of our biggest unfilled needs can be found. The body armor of the individual combat Marine. - We now have armor. It is good as far as it goes. It protects against relatively low-velocity fragments - shrapnel. Our present 'armor is a vest of ballistic nylon pads and rigid plates of doron. We also have a pair of armored drawers of ballis- tic nylon pads. These latter are affectionately known among Marines as the family jewel box. This armor is designed to protect the vital parts - to reduce the probability of a hit or wound killing the Marine. We need to extend body armor to the arms and legs to reduce the probability of a man becoming a casualty at all. We want to keep him on the battlefield as a fighting man. We don't want to lose him to the doctor. Whatever new ideas are necessary to make such armor possible - its attainment would be revolutionary. Our troops now have great confidence in their armor against ordinary shell fragments. Give them this new idea and every general staff in the world will have to make new calculations. That's the first item. Now for a second. This too has to do with the individual Marine. Our new methods of fighting places a premium on keeping the combat marine effective and reducing the supply prob- lem. One of our biggest problems - one that is with us every day - is food. Chow. Our present rations have great bulk. It takes a great effort and much time to.distribute this bulk on.the battlefield. In the attack we now rely principally on two types of rations.. One is the "C" ration. It takes 6 pounds per man per day.- It is in awkward packages.. The other type is the assault ration - the "K" type ration of World War IL It is relatively light and small. Both of these types have .a major defect. Troops exhausted to-the point of dropping wouldn't - or couldn't- eat them. They might take the meat part and eat that. But the rest of it was treated too many times like a low grade dog biscuit, which it did taste like. It was chock- full of vitamins, minerals, calorie, etc. But it was so dull and tasteless, so-hard to eat, that exhausted men dropped them on the ground and went to sleep rather than try to finish them. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: CIA-RDP81-01043R002200220009-0 UNCLASSIFIED 19 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Shaw UNCLASSIFIED What was the result? Under rugged combat conditions the troops lost their' resiliency - they could not bounce back. Too exhausted to eat the dull food given them, they never recovered from exhaustion - it pyramided: As' a result, tired men took more casualties-than they needed to. What we need is an assault ration of less than three pounds - so good that the troops will eat it all - so nourishing that they can exist on it for a Week or more. As you are probably aware, we Marines are justifiably proud of our well earned reputation for being the world's best fighting men. But we are not at all proud-about accepting ideas or suggestions from anyone that will help us continue to deserve that -reputation. We solicit your help in solving our problems so that we will be able to take some future Iwo Jima. Thank you for your attention. 20 UNCLASSIFIED ? L UNCLASSIFIED THE ORGANISATION OF BRITISH NAVAL RESEARCH AND DEVELOPMENT R. V. Alred Scientific Advisor to the Admiral British Joint Services Mission I feel a little out of place coming up here to talk on Organisation. It is a subject which receives so much attention in this country; a country where plans, schedules, programmes, slatings are all part of the daily life. The impact of this was well illustrated to me the other day. I was taking a British visitor around, showing him the sights of Washington - the Lincoln Memorial, the Jefferson, the Capitol. Finally we came to the Washington Monument, and of course he had to go up and see the magnificent views from the top. There were not many visitors there, but one little man seemed to be attracting 4 lot of attention; he kept going from window to window, obviously in a state of great excitement, havinga good look dawn from each window in turn. Finally, he couldn't contain his excitement any longer - he rushed up to the attendant and said "Say! When are you planning to get this into orbit". I am sure that some of you are wondering how and. why a talk on organisation found its way into a symposium.. having the theme "The Ocean as the Operating Environment of the Navy". -However; a little. reflection will show that it is an appropriate subject for this sym- posium. Just as equipment design has to take into account-4hp fluence of the sea) sq also has the organisation of the scieutists, who are responsible for deyeloping that equipment: They must'be- continually brought into contact with the oceans, with the ships, and with the men that man them. They. must live with. the navy, work with them, go to sea with them; otherwise they will produce equipment which doesn't do the job it was made for. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 21. UNCLASSIFIED ? UNCLASSIF IED Aired ? Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 In the United Kinbdom, naval scientists are spread amongst a large number of establishments whose work is controlled by various Admiralty Departments. These establishments are of two types, those concerned primarily with the development of material for fitting in ' the Fleet, and those concerned primarily with research and invest- igation. The responsibility for meeting the material needs of the navy rests with the various material Departments in Admiralty, such as the Department of Underwater Weapon Material, and the Department of Radio Equipment; these Departments are naval manned. The development work is carried out in establishments generally having a mixture of scientific and naval personnel, with a Chief Scientist and Naval Qa1Aain in dual responsibility. The naval personnel are there as working partners, not as controllers. A list of the more important development establishments, together with the responsible Department of each, is shown in Table 1. The purposes of these various establishments are self-evident from their names. 'Underwater Detection Establishment, Portland. Underwater Countermeasures and Weapons Establishment, Havant. Torpedo Experimental Establishment, Greenock. Admiralty Signal and Radar Establishment, Portsmouth. Admiralty Compass Observatory, Slough. Admiralty Engineering Laboratory, West Drayton. In addition there are a number of smaller facilites, such as the Underwater Launching Establishment, the Admiralty Oil Laboratory and the Central Dockyard Laboratory. The development establishments employ about half of our naval scientists. The organisation of the research establishments is differ- ent. These are manned and administered entirely by, civilian person- nel - scientific or engineering - and they report to Admiralty De- partments which are similarly civilian manned. Table 2 gives a list of the principal research establishments and their controlling Departments.' ? Admiralty Research Laboratory is mainly concerned with In- vestigations in the fields of-physics and mathematics - problems of oceanography; acoustics, fluid dynamics, etc. - Services Electronics Research Laboratory is responsible for research..on electron tubes, storage tubes, solid state devices, etc. 22 ? UNCLASSIFIED, Aired. UNCLASSIFIED Admiralty Materials Laboratory is concerned with physical and chemical research into new materials - plastics, ferrites, sili- cones, etc. Naval Construction Research Establishment is concerned with investigations relating to the design of ships' structures: Admiralty Experimental Works is concerned with investi- gations of hull shapes, stability of ships, etc. In addition to those mentioned on the table, there are various smAJler laboratories such as the Admiralty Hydro-Ballistic Research Establishment, the R. N. Physiological Laboratory, and the Admiralty Experimental Station at Perranporth. These laboratories are responsible for researches and in- vestigations not directly associated with dated naval requirements ; it is to these that we look mostly for our scientific breakthroughs. You will have noticed that a number of different Admiralty Departments are responsible for the work in the various research and development laboratories. It is however a feature of our or- ganisation that all the scientists in these various laboratories are in one scientific organisation - The Royal Naval Scientific Service -with central direction as regards careers, training, etc., and also as regards the science which they are applying in their various investigations. This gives a number of advantages compared with having completely separate organisations at the various labora- tories:- (a) The scientists have a common loyalty through a scientific chief direct to the Board of Admiralty; they have a common link with the Navy thereby. (b) There is greater freedom of movement of personnel, with no feeling of disloyalty to one's previoUs laboratory. (c) With the whole field of naval science availablel there is a greater chance of a scientist finding the work which Is .most congenial for him, and which best suits his .particular skills. There are a larger number of opportunities for .promotion to. higher posts (since consideration is not limited 'to persons in the particular establishment having the vacancy). (a.) Transfers are good for the scientist; they give him a Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 ? CIA-RDP81-01043R002200220009 0 UNCLASSIFIED 23 _r - Aired. UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 rejuvenation of outlook and a development of interest in new scien- tific fields. They are also good for the Navy; firstly, from the consequent cross-fertilisation of scientific ideas, which is es- sential if progress is to be maintained; secondly, from the more efficient use of available manpower, with transfer of effort as the changing needs of the Navy give emphasis first to one field and then to another. I referred earlier to the need for the scientist to under- stand the Navy and its needs. It is primarily in the development establishments that this understanding is fostered.- In these es- tablishments the naval officer and the scientist are mixed at all levels of responsibility.. I would like to dwell a little on the way they work together. In Admiralty Signal and Radar Establishment, as an example, there are about 270 graduate scientists, and about 40 naval officers of whom about 20 are line officers and 20 are electrical officers; these officers are on two-year appointments to A.S.R.E.s, and in most cases have had recent sea experience. The line officers are specialists in one or other aspect of naval war- fare, such as gunnery, navigation, communication - and their duties are manifold. They work as a member of a project team (under the scientist Project Leader) ensuring that equipments being developed will meet the needs of the Naval Staff; they advise their parent Staff Division in Admiralty of the progress of development, and of new possibilities; they maintain liaison with the appropriate naval training school concerning handbooks and training aids for the equip- ment under development. The electrical officer similarly works as a member of the project team paying particular attention to relia- bility and maintainability of equipment. This is where the naval officer gets to know the scierytist and his way of life. The naval officer asks for some.particular facility and the scientist wants to know the justification for its inclusion; the scientist dreams up a new circuit, and the naval officer wants to know whether it is as reliable as the old one. Discussion goes to and fro as different problems - and different. possibilities - arise. This is the breeding ground for .ideas - ideas for meeting a naval operational need with a piece of engineered hardware - ideas for new operational concepts based on a recent scientific invention. Then the scientist and naval officer take the-equipment to sea on trials -we have no separate Operational Development FOrce for the evaluation of our eqUipment. They learn at first hand how successful they have been in deciding amon&b the many confliting requirements and possibilities - and how uns'uccessf'ul, because there is always something they wish they had done differently. Some ay that development is slowed up because the scientist 24 UNCLASSIFIED Aired. UNCLASSIFIED is not free to develop equipment as simple engineering considerations would suggest. He must take into account the sometimes conflicting views of his naval officers. Further, if the naval officers are to have recent sea experience, they must change frequently. One then finds that different naval officers draw different conclusions from their sea experience, and a newcomer frequently tries to change things which have been pressed for by his predecessor. The scien- tist, who remains with the project throughout, must accordingly' develop a critical attitude as to May" not just "what" do you advise. And of course, it isn't long before he thinks he knows better than the naval officer - and one more scientist has then cleared the first hurdle in his naval education. TABLE 1 ADMIRALTY DEVELOPMENT ESTABLISHMENTS Establishment Controlling Directorate H.M. Underwater Detection Director of Underwater Weapon Establishment, Portland Material. H.M. Underwater Countermeasures Director of Underwater Weapon and Weapons Establishment, Havant Material. Torpedo Experimental Establish- Director of Underwater Weapon ment, Greenock. Material. Admiralty Signal and Radar Director of Radio Equipment. Establishment, Portsmouth. Admiralty Gunnery Establish- Director of Naval Ordnance. ment-, Portland. Admiralty Compass Observa- Director of Compass Department. tory, Slough. Admiralty Engineering Labora- Engineer in Chief. tory, West Dr'ayton. Declassified in Part- Sanitized Copy Approved forRelease2013/08/02 ? CIA RDP81 01043R00220022000q n UNCLASSIFIED 25 UNCLASSIFIED TABLE 2 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 oakum WEARCH ESTABLISHWITS Establishment Admiralty Research Laboratory, Teddington. Services Electronics Research Laboratory, Baldock. Admiralty Materials Laboratory, Holton Heath. Naval Construction Research Establishment, Dunfermline. Admiralty Experimental Works, Hasler. Controlling Directorate Director of Physical Research . Director of Physical Research. Director of Rngineering and Materials Research. Director of Naval Construction. Director of Naval Construction. UNCLASSIFIED 26 UNCLASSIFIED AN ADDRESS by Lee A. DuBridge President, California Institute of Technology It is a great pleasure to participate in this occasion in honor of two of my awn friends. It was my pleasure to be associ- ated with Bob Conrad during and after the war. I watched. with great interest especially the way in which he so effectively participated in the initial organization of the Office of Naval Research. His intelligent understanding and wise guidance in those days were determining factors in the great achievements which can be credited to ONR in the past ten years. I shall return to this subject later. The difficult and complex subject of this nation's regearch program in pure and applied science is being much discussed these days, and one hesitates to add any additional words to what is al- ready a voluminous literature on the subject. Especially do I ? hesitate. when I realize that I have no new thoughts to add; the best I can do is to arrange some old ideas in a different ,order, or to express them in different words. But I often. take compirt in a saying that is attributed to Oliver Wendell Holmes which goes, remember correctly, something like this: "Sometimes it is more important to emphasize the obvious than to elucidate the ascure." It is a wonderful quotation, for emphasizing the obvious iO one of my favorite occupations. Most speeches by.college presidents, of course, do the same thing. ********-****-X X-X-*XCX-34 3: ***********.********** X X * X-**-X-X *-X **if*** Text of remarks at the banquet of the Second,Symposima,on Basic. and Applied Science in the Navy sponsored by the Office of Naval Re search, El Cortez Hotel, San Diego, California, March 11, 1958. UNCLASSIFIED 27 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: CIA-RDP81-01043R002200220009-0 DuBridge UNCLASSIFIED Nevertheless, the nation's research program is an important subject and it is well that we explore fully and repeatedly. It is a complex problem, so.it pays to keep repeating and keep empha- sizing its fundamental aspects. It is an ever changing problem -- so that our emphasis must shift from time to time. Just now the country is engaged in a re-examination of its whole program of scientific research and development. This is all to the good -- and we can already see that worthwhile results will emerge. At the same time, we must be careful lest in the heat of excitement over recent events we act hastily or unwisely -- and thus cancel out the progress we may have made. Our current excitement was stimulated by the first launch- ings of earth satellites. And these events, which can truly be classed as man's first steps into space, have caused an avalanche of sudden interest in space research. If we can get an object 1000 miles off the earth, we can get off 10,000 miles, 100,000 miles -- to the mobil -- to Mars. True enough! But so what? Does this mean we must initiate a military conquest of the moon -- of all space? Are we going to have an American colony on the moon sonn -- a 49th state? ' Is the space around the earth soon to be filled. with flying platforms equipped to spy on all the earth, and to drop hydrogen bombs when hostile events appear to be taking place below? Unfortunately, these are not flippant questions; for all of these things and many more still more fabulous and flamboyant ones are being proposed and apparently seriously discussed in the hails of Congress, of the Pentagon, and in the columns of newspapers and magazines. Thus we are uncomfortably 'close to the situation where one of the- great technical achievements in man's history, instead of stimulating a vastly improved and valuable program of real re- search, is being allayed to convert us into a- nation of space 'cadets in which. billions of dollars will be wasted on fanciful and fruit- less and. ill-conceived projects, while real scientific research is neglected or even destroyed. So, with your permission, I should like to look at this problem very briefly in a very elementary way and ask how we can use the challenge of Sputnik to enhance rather than damage our nation "s scientific strength'. We'have the opportunity of a generation to improve our research. program. Let us not let it slip from us by diverting our attention to chasing butterflies. UNCLASSIFIED 28 UNCLASSIFIED Du Bri. dg e Let us start by trying to clear up one simple matter. Let us remember that launching objects into space is not In itself a . scientific achievement. It is an achievement of engineering or tech- nology. The scientific problems relating to orbits in gravitational fields were solved by Kepler and Newton nearly 300 years ago. Newton computed the speed. with which an object would have to be hurled in a horizontal direction to get into a stable orbit around the earth. But it took nearly 300 years of technological develop- menta in-rocketry, electronics, navigation, control and similar fields to accomplish the job. I am not denying that many good scientists cOntributed to these technological developments, nor that it did not take many discoveries in basic science to make them pos- sible. But rocket launching is still a highly developed technology and is not a branch of science. That doesn't make rocketry any less interesting or less important or less valuable; but let us be. careful of our terminology. But, like many branches of technology, rocketry can be a very useful tool for the scientist and I think it is very important that we develop this tool to the utmost and use it boldly and intel- ligently for scientific purposes. In order to discuss this matter, however, it is necessary first to clear away some illusions, some delusions -- and some down- right lied. We need to remind ourselves that just because a couple of objects are now traveling around the earth in stable orbits is no sign that all of Buck Rogers' adventures and achievements are immediately possible or desirable. I admit that to deny the im- mediate possibility or feasibility of some of the common Buck Rogers notions is to open myself to the charge of being a shortsighted old mossback. That is a risk I will have to take. And I am going to start out taking risks in a big way by saying flatly and firmly that I do not believe that the conquest. and occupation of the moon-have-the slightest military value or interest. Nor do I believe that. satellites floating around the earth are of the slightest use, in the foreseeable future, as bombing platforms or, indeed, for carrying out any other hostile act against an enemy except' spying On him. I think that the physicists and engineers who are listening to me will readily understand what I mean when I question the value' of a satellite as a weapon-launching platform. People who are used to flying in, airplanes, however, have grdwn u*Sed to the idea that if you drop something from a plane it falls to the earth -- and, indeed, if you just let go of the Object at exactly 'the right place 29 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 ? C UNCLASSIFIED UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 DuBridge you can hit anything you please. Many such people find it hard to believe th0.-t if you try to drop an object frdm a satellite nothing happenp. Exactly. nothing! The object stays right there with you. Even if WU give it a moderate push it will separate itself from you but slightly -- and then simply become another satellite, circling the earth alongside of the vehicle from which it was ejected. If . you gave the object a more vigorous push, and in the backward di- rection, it would, start falling to the earth -- but as it fell it would Pifck, up speed, and since its angular momentum would remain constant it, would simply-fall to a lower orbit and rotate there with a shorter period -- and at a higher linear speed. There is, of coa#se, the possibility that by firing our bomb backward from the vehicle with a rocket blast one could con- ceivably bring the bomb to a condition of zero angular momentum at such a point that it would fall vertically and hit the target -- if the earth's rotation brought it into line at just the right instant. But, knowing the difficulty of accurate bombing from an airplane at,39,000 feet going 500 miles per hour (or 8 miles per minute), I defy anyone to be optimistic in the near future about accurate retrobombing from a vehicle a million feet above the earth and going 18,000 miles per hour, which is 5 miles per second.- I don't say that this is ultimately impossible. I only say I don't see any sense to :it when we will soon be able to launch ballistic missiles so much more accurately, effectively and econo- mically, and_ hit any place we please without ever leaving the sur- face of the earth at all. Paradoxically, the large rocket has opened up. the conquest of space; but for military purposes, has Made space undecessary. But, of course, our space cadet replies by saying that he is going to place a stationary platform above the earth which can be i'apeuvered around like a magic carpet and from which a bomb can be droPped at will on any point. 'But there are several minor 'dif- ficulties with that idea too. First, a platform which remains for a- long time above a single point on the earth is not 'stationary 'at all, but is in an orbit which is rotating around the earth with the same speed as the earth's rotation -- namely, once in 24 hours, This is the stable period for an orbit which is about 23,000 miles 4p -- not a very handy bombing altitude! And a l'ooloab released from such a vehicle would not fall at all, but would have to be ejedted backward as 'before. Furthermore, one would be confined to targets exactly on the earth's equator, for that is the only great -circle above which there can be an orbit whieh does not alter its lati- ? tude, and above which the vehicle could remain apparently UNCLASSIFIED 30 UNCLASSIFIED DuBridge stationary. A stationary space platform at other latitudes is just not feasible. And who wants to bomb anything on the equator? Fina3 1 yl of course, 3)1.1..r space errthnslast retreats to the moon and says he will launch his missiles from there. Well, more power to him! He'll find the temperature a bit variable (boiling water by day; liquid air by night!); will find the lack of air, water and any appreciable or usable source of energy a bit incon- venient; and will be bothered by the logistic problem of shooting his materials and supplies and weapons up there in the first place. Why shoot a load of explosives 240,000 miles to the moon, then 240,000 miles back to hit a target only 5000 miles away is more than I can understand. In addition, I'll guarantee to shoot. 1000 mis- siles from the U. S. to Moscow while our moon man is waiting 12 hours, more or less, for the earth to turn around to bring Moscow into shooting position. Finally, it is interesting to note that a bomb projected on a zero-angular-momentum path from the moon to the earth will take just 5 days to get there! That's rather a long time of flight for any projectile. And we will hope the bombardier can figure correctly which side of the earth will be up by then. I haven't even begun to recite the real problems of space warfare. Any physicist could quickly figure out many more. True, he could also figure ways of getting around some of them. But I suggest that when we make ourselves believe that because we 've got one 30-pound satellite in orbit is justification for squandering billions of dollars in the so-call ed military conquest of space is jumping to premature conclusions, to say the least. Military rocketry, of course, is very important. ICBM's and IRBM's are an essential part of our arsenal, and let's don't let space dreams interfere with our getting some more good reliable rockets soon. Also earth satellites for military reconnaisance purposes will have considerable _utility -- and .I am all for them. And there may be other unforeseeable uses. There is plenty 'to do without trying to nail the American flag on the whole solar system by next week. But if some so far inarticulate military man should conclude that only a moderate. program of space technology would satisfy his needs, he might still be convinced that we need to go in for space cadet projects solely for prestige purposes. Sputnik certainly shocked us into realizing the importance of technical prestige in the world. Here, of course, we face. horribly difficult problems that 31 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED UNCLASSIFIED -EKOBridge Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 cannot be answered by scientific considerations alone. Granted there is no scientific advantage in giving the man in the moon a black eye or a scar on his cheek, haw many million dollars is it worth to do it anyway -- just to show the world what a great people we are? I honestly do not know. My awn advice would be to let the moon alone unless or until we are able to make a serious' attempt to get informa- tion of scientific value. And I should like to suggest that American scientists, as a group, adopt a similar position -- namely, that we are not .space cadets; that space stunts done just because they are stunts are not worthy of high priority unless they embody or assist in a real scientific experiment. Now there are indeed many scientific experiments that ought to be performed and that we should be working on. The ONR-IGY program is a sound one and should be pushed. If we get busy with these and other programs,, the scientific value will be great -- and to the thoughtful people of the world the propaganda value will also be great -- greater by far than for expensive and useless stunts. But America faces a grave problem at the present time. Can we indeed persuade the people of the country and persuade Congress that large funds should be spent for sound scientific experiments in space science and technology, but that we should not waste large sums on pseudo-military, pseudo-scientific or Buck Rogers projects? All of this, I must confess, seems to have little to do with the theme of this symposium on the science and technology of the oceans nor the purpose of tonight's dinner, which is to recognize a distinguished scientist for his contribution to the nation's military strength. But there are several connections between what I have said and what you are here for. Perhaps I should say I have thought up several excuses for talking to you tonight about satel- lite research. In the first place, the Robert Conrad medal is being awarded to a physicist who was a' pioneer in World War II in the development of rockets fOr important military uses -- rockets which found: wide use throughout the world and helped mightily to win many a battle on land,. sea, and in the air. Many of today's rocket tech- niques stem from the work he helped to get started. This same man also servea as a clOse adviser at the end of the war to those who were organizing the Office of Naval Research. Now I do not believe it is an exaggeration to say that the problems relating to the prosecution of scientific research which we faced at the end of World War II bear some resemblance to the problems'we face today. We as a nation in 1946 were somewhat 32 UNCLASSIFIED ??? UNCLASSIFIED DuBridg e flushed with the success of the technological projects in which we had been engaged during the wax. The fact that our physicists, chemists, mathematicians and other scientists had deserted their science and had become successful engineers had given rise to s. widespread impression that science and technology were the same , thing. "At last," some people said, "we have discovered the secret of scientific research. Just organize big laboratories, hire lots of workers, spend lots of-money and any scientific problem can be solved. Just look at the way the Army solved the problem of atomic energy." ' Fortunately those who were responsible for organizing the work of ONR had other ideas. The scientists in the great wartime laboratories of technology were about to return to their scientific laboratories in the univeisities. Haw were they going to be aided in getting their scientific work underway again? Haw were the universities to be helped to rebuild their shattered programs of research in basic science? And how were the laboratories of science to be enabled to make use of the great new techniques which had evolved during the war to aid in scientific exploration? It was a time of grave decision. The country might have decided that mili- tary technology was indistinguishable from basic science -- might have continued the wartime research in radar, rockets and atomic weapons to the exclusion of basic science. But a few people thought differently. Among them were Charles Lauritsen and Bob Conrad. They agreed that a way must be found to provide funds to the universities on a broad and free basis to aid in the re-establishment of basic science. And ONR was founded with that end in view. Years later, after the soundness of the ONR concept had been established, other agencies were created to assist in the task -- notably the National Science Foundation. But history will have to give the credit to ONR for blazing the trail and holding the fort during the critical post- war years. Possibly we are in a similar position today. The satellite fever has created the impression that rocket.technology'is science, that space cadets are the true scientists 'of' the future, and that the natiOn's only forward looking scholars are those Who are plan- ning to land on Mars. Fortunately, the nation's scientific strength is far great- er today than .it was in 1946. Fortunately, there are other agencies joined with ONR in -the promotion of science for its awn sake. But it may take the combined resources of all of us to make sure that we maintain and strengthen our programs of basic science,,that.we use the great new tools of space technology for sound scientific pur- poses, and that we do not fritter away valuable resources and valu- Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 33 UNCLASSIFIED DuBridge Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED able talent on useless Buck Rogers stunts, or on false conceptions of the military value of what is humorously called space conquest. We ought to be able to justify the scientific exploration of space for its awn sake, without pretending that it has a military value which it cannot possess. UNCLASSIFIED 34 ? I I I t , 1 CONFIDENTIAL A SURVEY OF HYDROBIOLOGICAL ASPECTS OF NAVAL OPERATIONS S. R. GALLER, Navy-Department Office of Naval Research Washington 25, D. C. The term hydrobiology like its protean relative, oceanography, may mean various things to the various scientific specialists who collectively have established its rather nebulous boundries. For our purpose, however, hydrobiology may be defined as the interrelationship of the biological components with the physical and chemical factors of marine, estuarine, and freshwater environments. It includes biological oceanography as well as limnology. In addition, hydrobiology serves as a convenient focal point for data derived from field and laboratory studies and experimental investigations in most of the classic biological disciplines. In recent years, the United States Navy has developed a sub- stantial interest in hydrobiology for it has become increasingly apparent that a variety of problems which confront the Navy in carrying out its assigned mission, stem from hydrobiological origins. In additon, information derived fromhydrobiological investigations offer a basis for the eventual development of new and improved techniques, materials, components and systems which will be useful in Naval operations. Let us proceed to review some of the U. S.,Navy-,Is interests in hydrobiological research. The prevention of marine biological deterioration and fouling has been a problem of. concern to the world's navies since the days of antiquity. An inventory of the techniques, materials and gadgets which hive been advocated and tried in this field would make fascinating reading indeed since in effect it would represent a history of man's scientific interests and activities relating to the sea. His efforts in discovering a means for preventing marine' Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 35 CONFIDENTIAL Galler CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 deterioration and fouling, however, have not been crowned with spectacular success. The problem continues to be a serious one both in terms of financial losses and operational impairments. The Prevention of Deterioration Center of the National Research Council has estimated that losses from marine deterioration in the United States run about $500 million annually. The Navy, in spite. of its research, development and maintenance efforts to date; suffers annual dosses estimated at between $50 million and $75 Million. More serious, however, is the reduction in .operational efficiency which results from marine biological deterioration and fouling. A senior Naval Officer once sized up the problem very neatly by stating that basically the service life of outboard equipment was prOportional to its susceptability of attack by marine boring and fouling agents. To the best of our knowledge, this thesis has not been subjected to vigorous statistical analysis. Nevertheless, one cannot argue with the evidence that marine plants and animals do attach themselves to the surfaces of man-made objects inthe sea including pilings, ship and boat keels, hydrophones, transducer domes, harbor defense nets, moored mines, etc. Nor can we argue with the evidence that many of these organisms are able to attack these objects eventually destroying or greatly reducing their service life. The aforegoing does not imply a criticism of the existing research and development activities aimed at controlling this problem. Indeed, the phenolic resins which were developed to reduce fouling on keels, and the many marine wood preservatives which have been developed since World War II have greatly increased the field service life of a variety of Navy equipments. The fact remains, however, that most of the preservatives in current use were developed without a knowledge of their mode of action. Consequently, a large assortment of treatments and preservatives have to be employed to control marine boring and fouling pests in the many geographic,and enviornmental situations. in which the Navy carries on its operations. No one -of the marine preservatives and/or treatments in common use today may be expected to provide full protection in every environmental situation of current or potential concern to the Navy. This is true interestingly enough in spite of the fact that, although almost all phyla contribute to deterioration damage, most of -such damage throughout the world is caused by organisms largely confined to two phyla: the Phylum Mollusca (the Teredo or ship worm), and the Phylum Arthropoda, Class Crustacea7(ITTinoria or wood gribble, Balanus or barnacle). ? 36 CONFIDENTIAL f. Ga her CONFIDENTIAL One of the objectives of the hydrobiology research program is to obtain sufficient information regarding the chain of vital processes of the organisms responsible for deterioration and fouling to discover those "links" which appear to be most susceptable to inter- ference and, thus, control. On this basis, it is possible to design chemical inhibitors for the control of the animals themselves without regard to their geographic or environmental situations. Such an objective, of course, calls for a well coordinated research program in hydrobiology including marine ecological, physiological and biochemical investigations. That the results will be well worth the effort is evidenced by the fact that such diverse fields as chemotherapy and insect control have made outstanding advances in recent years based on fundamental knowledge of the organisms involved. Even at the present annual level of Naval support of basic hydro- biological researchl(less.than one quarter of one percent of the estimated annual loss to the Navy from marine deterioration)the program is yielding rich dividends in knowledge for the control of these ubiquitous pests. Marine organisms may be important causes of interference with underwater acoustic communication and detection systems. Since before World War II the literature has referred to the so-called "false target" problem caused by marine animals which represent acoustic targets sufficiently similar to targets of operational significance to present a serious problem to the sonar man. The World War II reports of submarine war patrols are replete with references to hazards resulting from sonar contacts with false targets. Even today, using equipment with a high degree of resolution, reports of false targets are not infrequent. The so-called deep scattering layer, discovered in the early days of World War II is a classic example of biological interference with the transmission and reception of acoustic energies underwater. Another kind of biological interference is thAt which is represented by marine biological sound producers including fishes, shrimps, crabs, porpoises, etc. As most of us know, the sea is not the stark, silent deep as represented in the fiction of yester year. Indeed, acoustically it is more akin to Broadway and Times Square during the rush hour, and it is this feature, in large measure of biological origin, which constitutes a problem in the operation of passive listening devices. The ambient noise produced by a large school of sound emitting fishes can oftentimes result in a very poor signal to -noise ratio. 37 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL Galler CONFIDaITIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Finally, there is an increasing body of scientific evidence becoming available which definitely implicates very small planktonic organisms as primary causes of biological interference with the propagation of acoustic energies underwater. Until recently, the acousticists and physicists concerned with submarine acoustics were of the opinion that very small biological particulates in the water were of insufficient acoustic target size to constitute an . attenuation problem. While this assumption appeared to be valid when considering the acoustic effects of individual small organisms the fact remains that usually these individuals are not homogeneously distributed throughout the water column. On the contrary, they tend to congregate in response to changes in some of the factors of their local environment. Thus, for example, changes in light intensity or changes in the density of the medium may produce upward or downward movements of whole populations of planktonic animals. The result of congregation may be the development of a very substantial acoustic target. The hope of developing a control of biological acoustic inter- ference, except in very highly localized environments, is utopian indeed. However, there is one kind of information which can be obtained from basic hydrobiological research which would be of immediate practical value to the Navy. It should be noted that the types of biological interference with underwater propagation of acoustic energies have one characteristic in common. In each instance it results from the presence of individuals or populations of marine organisms which respond to changes in environmental factors. in other words, marine animals and plants, like terrestrial fauna and flora, exhibit seasonal and geographic variation in population, especially the populations on the continental shelf. It would be of great value to the Navy to be provided with data which could be used to anticipate the probabilities of encountering marine animal populations at various geographic locations according to species, seasons, distance from shore, depth, etc. Such information might well play an important role in planning a fleet exercise or operation. It would certainly be of considerable value to the submarinerlfcr example, in predicting-underwater sound conditions likely to be - encountered, and in interpreting and evaluating ,acoustic information obtained in the field. During the aforegoing discussion an effort has been made to illustrate in some detail a few of the Navy's interests in hydro- biology. There are a number of other hydrobiological problems of considerable concern to the Navy. The limitations of space do not permit a detailed presentation of these problems. However, it is hoped that the following inventary.will serve to illustrate the diversity of Naval interests in thie field. 38 CONFIDENTIAL Geller CONFIDENTIAL 1. Hydrobiological aspects of surface and submarine concealment: ? Bioluminescence: During certain seasons of the year and in certain geographic locations, as for example, the Central Pacific Ocean, blooms of bioluminescent organisms occur in the oceanic waters at the surface and down to considerable depths brightly illuminating the sea when disturbed mechanically. Under these conditions a surface ship or a submarine close to the surface, a mine field or even a swimmer may produce-sufficient disturbance of the water to result in the production of bioluminescent wakes and bow waves which can be detected easily from' aircraft. Ambient noise:' The changes in the quality and quantity of ambient noise of a biological origin due to the presence of a submarine, a newly laid mine or a team of underwater swimmers can increase the probability of detection by an alert enemy. 2. Survival at sea: Successful survival at sea under emergency Conditions may owe much to our knowledge of the habits and identities of dangerous organisms as well as the edible flora and fauna of the oceans. Similarly the chances for surviving a period of isolation on land is in large measure dependent upon our ability to discriminate the edible species of animal and plant from the poisonous and venomous forms. It is considered quite important to develop a series of antitoxins and antivenoms for self treatment in the field in instances when the individual has ingested poisonous forms or when he has been injured by the venomous freshwater or marine fishes which are abundant in many localities of interest to the Navy. 3. Protection of underwater swimmers: This problem in Large measure may be considered as part of the emergency.survival problem. However, the necessity for minimizing the chances of failure of a mission involving underl4atef' swimmers lends additional emphasis to the need for developing an effective deterrent against sharks, barracuda and other carniVb.rous animals. Also, the underwater swimmer is likely to Cote into contact with many carnivoi'ous and venomous marine ?pecide usually not encountered by the life raft or island-dwelling urvl.V.-oi*, 66 far example, moray eels, poisonous corals, sting rays, poisonous sea urchins, etc. 39 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Galler CONFIDENTIAL Thus, it is important that the underwater swimmer be provided not only with a practical knowledge of the behavior and habitats of these organisms but also with a means of coping with them or the injuries which they may inflict. I. The role of marine biota in oceanic radioactive contamination: As the Navy provides itself with an increasing number and variety of submarine nuclear weapons it must become increasingly concerned with the problem of controlling radioactive contamination resulting from their use. Toward this-end, it is essential that we enhance our knowledge of the roles of marine flora and fauna both in. the .mitigation of radioactive contamination and in the spreading of contamination up through the food chain. S. The biological effects of underwater blasts: Closely related to the problem of controlling radioactive contamination is the problem of minimizing damage to commercial and game fish populations resulting from underwater explosive tests. The Navy through its hydrobiological research program is cooperating closely with State and Federal conservation agencies in developing a body of knowledge regarding the seasonal and geographic distribu- tion of marine and estuarine fisheries. This information is invaluable in planning effective underwater explosive tests with a minimum of damage to valuable fish and shellfish species. In concluding this phase of our discussion it should be mentioned that there are important hydrobiological implications in such operations as promining and mine countermeasures as well as anti-submarine warfare. Those considerations, however, must be reserved for secret presentation. The aforegoing has dealt largely with Naval'problems of hydrObiological origin. The research program in hydrobiology, in addition, plays a major role in encouraging investigations of marine and aquatic animals and plants as biological models exhibiting characteristics which are of interest to the Naval scientist. The hydrodynamic 'characteristics and mechanisms of propulsion of many ? of these animals are of interest to a variety of Naval specialists including surface ship and submarine designers,. Also, the abilities of certain marine And freshwater fishes to detect and identify targets and home on them from great distances deserves the attention of Naval scientists. The so-called ? 40 CONFIDENTIAL a Caller CONFIDENTIAL "long range" navigational skills of migratory fished by which they are able in some manner presently-unknown to man, to migrate. over great distances and to arrive with great accuracy at destinations which in many cases proved to be the points of origin from which they migrated from 3-7 years earlier, is of obvious interest to the Navy. An elucidation of these phenomena may in the establishment of new concepts and eventually to the development of new and improved mechanical or electronic sensors of direct value to the Navy. No discussion of the Navy's program in hydrobiological research would be complete without mention of the possibilities of employing such biological agents as photosynthetic algae as a means of improving atmosphere control in enclosed spaces such as submarines. In this connection, it should also be mentioned that devices patterned after the gill systems of fishes deserve more attention as another possibility for improving our gas exchange systems in submarines. In conclusion, the hydrobiology research program sponsored by the Office of Naval Research is designed to provide the basic information required to control or eliminate a number of problems of current concern to the Navy. The program is also designed to provide a foundation of information which may eventually lead to the development of new and improved techniques, materials and equipments which will be useful in furthering the Navy's mission. f' It is noteworthy that hydrobiology has long constituted a field of interest to the Navy of the U.S.S.R. At present, the Russian Naval Adademy is the only one known to the writer which requires its students to take a course in "Naval hydrobiology" which covers mostof the problems presented in this paper.*. This writer, as a matter of personal curiosity; recently endeavored to compare the extent of USSR support of hydrobiological research (as noted in the open scientific literature) which he considered to have a relevance to Naval interests, with support of hydrobiology in this country. Since there was no way of determining the actual Russian expenditures in this research area, an estimate was made of how much it would cost to support a similar program in this country. The figures, although admittedly a crude estimatelnever- theless, may provide Some basis for comparison. It-was estimated that the hydrobiology program being conducted in the USSR (knowledge of which was derived from the open literature) would require approximately 18.3 million dollars for its support in the United States. 41 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL RESEARCH PROBLEMS OF SUBMARINE . OPERATIONS UNDER-ICE IN TBE ARCTIC OCEAN Dr. Waldo K. Lyon U..S..Navy Electronics Laboratory San Diego 52, California During the past eleven years, the U. S. Fleet has conducted a small but persistent study of submarine operations in ice covered seas. This study has given the diesel submarine the ability to live and work in ice fringe areas, the marginal zone from open ocean to about fifty miles inside the arctic pack. With the advent of the nuclear powered submarine into the Arctic Ocean, as demonstrated by USS NAUTILUS last September, the vast north coast of the USSR was opened to patrol by submarine. It becomes, therefore, an exposed, ocean coastline as extensive as the U. S. Canadian coast from San Diego to the Bering Strait. A submarine patrol from Pearl Harbor to Murmansk is no greater than from Pearl Harbor to Hong Kong. Furthermore, the ice canopy overhead provides unevalled protection against air or surface nraft or, missile. ? Though the arctic submarine closes the circle around the . .USSR, our advantage is not unilateral because the ice gives the Soviet submarines cover from their arctic ports through Denmark Strait to our North Atlantic coast. Furthermore, northern Canada now becomes a set of-submarine passage ways including'Hudson Bay; which reaches near to the heartland of the American Continent. Submarine operations under sea ice have generated questions of ship engineering and properties of the ocean requiring immediate empirical answers. In this brief review; we cdn only state the questions. We shall also try to indicate which areas require . research. It is long term research in ocean-cryology that will give Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 42 CONFIDENTIAL Lyon CONFIDENTIAL UB the. understanding of sea. ice we now lack and that will discover new concepts for submarines to exploit in the Arctic Ocean. Obviously, navigation under sea ice means knowing ship's position similarly, to open water, and similarly to open, water, if we use bottom features to fix position, we need precise, detailed bathy- metric charts of the Arctic Ocean and its approaches. For twelve years, the USSR has been actively engaged in charting the arctic ocean by aircraft landings on the sea ice. Their published stations are shown in Figure 1. Their published bathymetric_chart is shown in _Fig: 1 - USSR Observations by aircraft landings' 43 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Lyon CONFIDENTIAL Figure 2. Ten years ago, we thought the Arctic Ocean to be a flat CXISIA APt ???? aba4 CCCCC Mire CCCCCCCCC ? 04CAIIA ? 1, akl -....., , 4v.. al 14- vt.., I/ \-:-- ? ,,,,,I _IA ,,,...? (. ,?;-'1-f---,:---::!..):--.:-.54,.: ...._ d.4.-cg., 4 I,:,I 4..":::!. `,21.-> *. ? .z.;'':':?-?%??? -...'."-.7.--..??.::::.ZI Ij 1 k: 1 ,7*.?^147.'l ??? ,.......7,42,A?fr,L- , 2.7." I I N :, ..- I 'Th::. .-?"' \ -? ? j_;\;-,., ....ii? . ? i .,...,/ !,.,1:1.,x .,. Fig. 2 - USSR Bathymetic and current chart basin but we now find that it contains the Lomonosov mountain range and has complex bottom features valuable for navigation by bathymetry. In contrast, the United States has two floating ice bases, namely Ice Island T-3 and the iqy ice floe Station A. We must catch up on bottom charting by using submarines which .surface periodically to precisely fix position by radio methods and which, for example, use bottom planted sonar 'beacons for guidance to develop the features -of seamount. Ti.' S. and Canadian icebreakers must get on with the task of surveying the fringe areas, the Greenland Sea, the Lincoln Sea and the Canadian Archipelago. ' Navigation by bathymetry is the old, reliable passive method. Another old .reliable method is by star fix. Star fixes can be made much' more accurate in ice covered than in open sea because the stable surface permits the use of the most precise theodolite and 44 CONFIDENTIAL Lyon CONFIDENTIAL star angles can be cut with an accuracy-equivalent to that of shore based observation. Star fixes may be particularly useful in clear sky, dark period of winter. Of course, any electronic aid, e.g. LORAN, EPI, DECCA, RADUX is applicable to the Arctic. Ocean'. However, to use the electronic aid, to take.a star fix, to deliver a.missile, or to act as radar picket requires surfacing in sea ice, and therein lies the major problem. To date, .a topside sonar system has been the principal tool for under ice diving? The sonar system is required: (a) to evaluate the type, distribution andthickness of the ice canopy; (b) to guide ascents into water openings or brash, ice, or (c) to find the thin, recently frozen sheet ice in leads during winter operations. Evaluation of type of ice canopy, for example, giant floe, small floes or brash ice, is required in order to decide in any particular area if speed should be reduced because probability of existence of a.lead, or small water opening, or brash ice, is sufficiently high to warrant search for the particular opening in which to surface. The topside sonars must then guide the ascent into the opening by detection of all ice blocks above the vessel throughout the ascent, indicating their thickness and approximate size. The topside hull should be smooth, curved clean swept in order to permit surfacing in ice cluttered leads or brash ice, or breaking through thin ice sheet which often forms over leads at any season. All through the hull equipment (radar, periscope, antenna, sonar and snorkel) should retract flush with protective covers into the topside surface,. This null type is essential to extending submarine operations into the winter season. ? . To date, our submarine experience has 'been-entirely with summertime conditiohs, and the vertical 'ascentinto a water opening - has been used exclusively,. The procedure is obvious. Let us assume the submarine is under an ice canopy similar to that shown in Figure 3, which is a composite of vertical photographs taken at an altitude of 3500 ft. over the Beaufort.Sea in September. The conventional scanning sonar gives a fairly accurate pictureof_the canopy over a 2000 yd. circle, 'showing. major openings and ice floes. A vertical sonar screen is used to observe the ice directly above the submarine and'to determine its thickness. This vertical screen consists of five echo sounders evenly spaced along the topside of the boat. The submarine must maneuver directly under the water opening, observe 45 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL Fig. 3 - Vertical Photograph of Sea Ice. Scale 400 Yds.: Inch CONFIDENTIAL CONFIDENTIAL relative drifts of sea ice overhead and make the stationary, vertical ascent, correcting as necessary to match drift of the sea ice. This is a slow process, taking, perhaps forty minutes to accomplish, but is necessary because of the present configured hull and the susceptibility of topside equipments to cThnge from collision with even small pieces of ice. It is believed that with a clean, protected topside hull the ascent should be at slant angle, driving up with controlled speed into the slot in the ice canopy. Let us suppose, at a cruising depth of 600 ft., the decision has been made that the ice canopy is satisfactory for surfacing and speed has bean reduced to about 5 knots. Suppose we use a sonar scanner of 2 total beam angle and sweep pe surface 700 yds. ahead and find a slot'sufficiently large. This 2 scanner should "see" all ice pieces 15 yds, in diameter or greater. While scanning our chosen spot of surface, which is perhaps about a 500 ft. square, we are moving ahead and at 500 yds. we start a 20o ascent, from 600 ft., controlling speed and buoyancy. At 500 yds., we should "see" all pieces of ice at least 12 yds. in diameter, moving on, we can detect smaller ice pieces and cut down the area scanned. At 150 yds. from our chosen surfacing touch point, keel depth 240 ft., we should detect pieces 6 ft. in diameter, or greater, i.e., something about 5 tons or greater. From here in to breaking surface, the scanner is looking at grazing angle to the surface and gives the final check of clear length of runway ahead of our touch point. It is then housed behind heavy steel cover to protect against collision with small ice chunks on breaking surface. From 150 yds. in to breaking surface, we use the vertical topside screen formed by five echo sounders spaced along the topside to tell us what shows up above the hull during the final break through to surface. Keep in mind, it is the vertical beam that tells us the ice thickness; the slant angle, scanning beam does not. Thesetopside vertical echo . sounders work right up to breaking surface and can sustain direct- collision with ice, as has been demonstrated on NAUTILUS and by the echo sounder in any icebreaker hull. ' In addition to the example just described of surfacing in water openings, the submarine must be capable of surfacing in brash ice of nearly 100% coverage as illustrdted by Figure 4. The 'photo- graph shows REDFISH (SS 395), a Fleet class submarine, on station in brash ice 110 miles northeast of Pt. Barrow during,August 1952. For five days REDFISH remained on this station, then without benefit of aerial reconnaissance or any other form of assistance and under complete radio silence, REDFISH submerged and proceeded under ice to find a water opening nine hours later in which to ascend. After. batteries were recharged, another dive of three hours brought open CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Lyon CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 _ `-?r?-??swv...t. _ -aff ?? ? ???1"' -?-? ? ajigiV 1,4 14..1-- ?z-,..t ? - ? $.44 . 1.4-4.t.:? ? 4. Fig. 4 - USS REDFISH (SS395) in Sea Ice, Beaufort Sea water near the Alaskan coast. These dives required more knowledge of the sea ice and detailed oceanography of the area than the more spectacular cruise of NAUTILUS last summer. Under brash ice, the 20 beam scanner at slant angle would show practically a continuous ice sheet but at vertical position would detect the brash character. The ascent would be similar to our previous example to a keel. depth of about 75 ft.) then by vertical ascent and to choose a satisfactory spot to "shoulder" a way through the brash ice. A third'typical situation iS the shallow area i.e. water 150 ft. deep, and there-are many shallow areas of operational sign- -ificance, for-example, the.Bering Sea, the Chukchi Sea, the great Siberian shelf and parts of the Kara Sea. In the shallow area, the 2 bean scanner serves the prime function of estimating depth-of any massive ice ahead and determining the dimensions of a water opening ' in which an 'ascent is attempted. Extending to winter operations, we have no experience except in the Bering Sea where surfacing should be possible wherever desired. In the Arctic Ocean, we must make winter* observations for coverage, thickness and existence of fresh frozen leads. Can the submarine break through these ice sheets, or must we provide heat or 48 s CONFIDENTIAL ? ? ? Lyon CONFIDENTIAL explosive cutting methods? The winter operation, I believe you realize, is a vast problem, yet to be defined, let alone studied. We depend on sonar to guide our ascents in sea ice; yet, we must admit we know very little about the acoustic properties of sea ice. From analysis of records taken on the topside vertical echo sounders, which operate at about 22 Kc, we believe summertime sea ice to be a volume scatterer at this frequency. It is acoustically like a ship's wake. 22 Kc sound is scattered back from .throughout the entire volume of the ice and not from its bottom interface - in fact, this bottom interface is difficult to describe. A piece of over- turned sea ice is shown in Figure 5, which illustrates' the open Fig. 5 - Overturned Sea Ice Showing Honeycomb Structure. (Scale About 2ft:inch) Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 49 CONFIDENTIAL Lyon CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 structure of the ice. This structure is free flooding and holds many 'air bubbles, which, as inwakes, are suspected to act as intense sound scatterers. Sound observations have been made at one other frequency, namely, 1 Kc. These were conventional sound transmission runs to a distance of 100 miles under ice in the Beaufort Sea. It was these sound observations that kept REDFISH on station in the sea ice previously described and shown in Figure 4. The results indicate that at this low frequency the sea ice (in summertime) acts not as an intense scatterer but as a thin refracting layer against the near perfect reflector of the air boundry. The top reflecting boundry is not necessarily the physical topside surface of the sea ice because of the porosity of the sea ice. At 1 Kc. the reflecting interface is likely in the vicinity of the hydrostatic level of the sea within the ice structure; hence) giving a uniform reflecting boundry irrespective of large variation of height of ice above the sea surface. The obvious questions: what are the properties at other frequencies? At what frequency does scattering take over? What about changes:as freeze up sets in, autumn, winter and spring? There is here a long term research of the physics of sea ice, its growth and relationships to its acoustical properties. In closing, I wish to simply mention other problems which we face: 1. The mechanical and thermal properties of sea ice as a function of growth, history and season so that we can design break throUgh methods, thermal and/or mechanical. 2. The optical properties, including the amount of natural light under ice, the transparency of the water and the amount of light scattering, in order, for example, to estimate the assistance to be expected from a TV camera during the last. 100 ft. of' ascent into the,ice-canopy.. 3. The electrical properties to determine, for -example., ? radid:transmission.characteristics dver sea ice with seasonal changes in salihity,-ca,ceptibh of VLF under sea ice by a trailing floating antenna. ? ? 4; Sea ice formation on wet surfaces, a problem somewhat analagouss to icing on aircraft. For example, a most serious problem 146-are presently working on is the prevention of sea icing in snorkel head valves 'when snorkeling undei.'winter conditions ofEir suction temperatures below the freezing point and loaded with sea spray. Other problems will appear in midwinter Arctic Ocean operations when periscope, antenna, radar, or missile emerges from 50 CONFIDENTIAL ???? ? Lyon CONFIDENTIAL below ice into air temperatures of -356F. 5. Finally, a whole host of operational problems require study, for example, the detection and attack of another boat under ice, dr the weapon and attack method on surface ships when in ice, or the use of mines uhder ice. Perhaps, during 1957, the arctic submarine has come of age through the advent of nuclear power. Five or six years ago, our official position was that the transarctic submarine was still a fantasy. Yet, today the Chief of Naval Operations should, perhaps, consider adding a third force command to that of ComSubPAC and- ComSubLANT, namely, ComSubARC. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 51 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED ' REQUIREMENTS IN MILITARY OCEANOGRAPHY John Lyman U. S. Navy Hydrographic Office Washington 25, D. C. The term "military oceanography" was proposed by Seiwell (1, 2) with a rather restricted connotation, but I propose here to give it a much broader one. To begin with, we need a definition of "oceanography." Some practitioners in the field during the last decade have wasted what seems to me to be a great deal of effort in attempting to settle whether "oceanography" is in itself a separate science, or a group of sciences; or whether it is a fraction of each of a number of inter-related disciplines; or whether perhaps it is not "oceano- graphy" at all, but "oceanology" or "the marine sciences." I prefer to define oceanography as the scientific basis of seamanship, just as physics is the base of engineering, or nautical astronomy of celestial navigation, or chemistry of soap-manufacturing. "Military oceanography," then, is the scientific basis of seamanship as it concerns military operations, taking the term "military" in its most inclusive sense. Military oceanography differs from the kind of oceanography commonly carried on for purely civilian pursuits in that it involves consideration of factors affecting devices such as sUbm. azines or ordnance., affecting problems as-detection or secure communications, and affecting operation's such as wholesale destruction or delivery of vast quantities of men and material where no port facilities exist. On the other hand, militany oceanography is for the most part unconcerned with much of the scientific basis of fishery seamanship -- the plankton counts; UNCLASSIFIED 52 LYMAN ? UNCLASSIFIED analyses for dissolved gases, nutriehts, and trace elements; and year-crass studies that currently occupy such an important place in fishery investigations. The most significant military use of oceanography lies in its ability to predict occurrences in the sea. Some phenomena affect- ihg the seaman have .been under observation for so long that-their prediction is taken for granted. Both the mariner and the seaside dweller have such confidence in the ability of the tide tables to predict sea level to 2 or 3 feet -- only 0.02% or 0.03% of the average depth of the ocean -- that -events like the North Sea flood of January 1953 or Hurricanes Connie and Diane in New England in 1955 or Audrey in Louisiana in 1957 become horrible calamities. Yet model studies, theoretical computations, and other analyses made after the events have shown. that the extraordinary heights of sea level reached in each of these cases have a firmly predict- able basis. Unfortunately, these predictions cannot be issued a year or even a week in advance, and the complexity of the organi- zation required to produce storm-tide forecasts and the public inconvenience that can result from a premature forecast that fails to be verified are factors tending to hinder development of comprehensive prediction services. On the other hand, the tsunami warning service of the U. S. Coast & Geodetic Survey in the Pacific, which is based on the simple fact that earthquake waves arrive long before ocean waves, is successful and valuable service, even though not every potential earthquake seems to produce a tsunami, and thus occasional warnings are distributed for waves that never materialize. Two case histories from recent oceanographic operations of the Hydrographic Office will further illustrate the value, of the prediction approach in seamanship. The first example is connected with the movement of cargo to the Arctic in connectibn with the construction and maintenance of the DEW-Line and other polar bases. When the -requirement for this movement was first laid on the Military Sea -Transport Service in 1951-, so I am told, it was accompanied by unseamanlike stipulations as to times and dates at which certain deliveries had to. be made in the North. Although the Navy and Coast Guard had been supplying weather stations and the Petroleum Researve for several years, there was a prevailing 53 savyau.nr.....doellOpestaZINUS, Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LYMAN UNCLASSIFIED impression that "ice is where you find it;" that nothing therefore could be done about it; that schedules could ignore its presence; and that the resulting damage had to be accepted. However, ice damage to MSTS vessels and other costs due to delay resulting from ice in 1951 reached the round total of $17,000,000,. a sum which unfortunitely had not been provided for in anyone's budget, and which even in the free-spending Korean War days was unacceptable to comptrollers. The.subseq'uent de- i.relopment by Hydro for MSTS of an ice-forecasting and recon- naissance service with the expenditure of considerably less .than $100;000 a year has been described by Bates, Kaminski, and Mooney (3). In 1952, costs of ice damage and delay to MSTS vessels were ,cut to $6,900,000; in 1953 they were only about $1,000,000; and the figure has stayed low in spite of greatly increased operations. In 1955, an exceptionally bad ice year, damage amounted to $4,800,000; in 1956 it was $2,100,000; and last year it was around $1,000,000. It would be ridiculous, of course, to claim that an expen- diture of $100,000 annually on oceanography led directly to savings of $10 or $15 million per annum. What manifestly has occurred, however, is an awareness on the part of those laying down the schedule requirements that it is no nore seamanlike to attempt to take a ship from one port to another when ice conditions are unsuitable along the route than to attempt to cross a bar in a ship drawing 28 feet when there is only 26 feet of water on the bar. In the latter case, we have the tide tables to guide us; in the ice situation, the accumulated observations and experience of a century were inadequate, and systematic reconnaissance by trained observers, a special reporting net, and. scientifically-based forecasts drawing on the principles of ice formation and drift, were required.. The second . example comes out of recent developments by Hydro in methods for improving transoceanic crogsings by surface vessels, from the standpoints of economy in time and fuel, comfort of personnel, and minimization of damage to ships and cargo. It is of -interest to point out that oceanography became recognized as a science through Maury's dealing with this identical problem 110 years ago (4). For sailing vessels Maury laid down routes based on climatological averages which can scarcely be improved on today (although some of the record voyages by sailing UNCLASSIFIED 54 LYMAN UNCLASSIFIED ships were on routes that differed widely from his recommendations). For steamers Maury was content to specify great-circle courses, and great. circle courses have been standard to the present day, far, far too long after the equipping of all ships with radio opened the door to the possibility of continuously monitoring their passages and furnishing guidance based on existing and predicted weather situations. At Hydro we have applied a technique for making wave predictions to the five-day forecasts obtained from the Weather Bureau, to produce long-range forecasts of wave conditions (5). Knowing, from log book analysis, how various vessel types are slowed down by wave ' conditions, we borrow a "minimum time- track" technique from modern airline practice, to determine the route which will get the ship to her destination most quickly (6). We have furnished daily recommended routes to most MSTS sailings for the past two winters; recently MSTS has cut one day off its scheduled transatlantic passenger schedules. Here there can be no argument as to the direct result of putting seamanship on a scientific basis, and a saving of approximately 10% in time at sea, with increased passenger comfort, is an achievement I am proud to report. What do we still need in military oceanography? Basically we need an increased awareness in the Navy that good seamanship ,involves science just as much as do the design and functioning of weapons, hulls, power plants, or communication systems. Specifically we need overall direction for putting all aspects of seamanship on a scientific basis. The Navy Once had -a Bill-eau of Navigation, whose chief ornaments were the Naval Observatory and the Hydro- graphic Office; but it turned into..a Bureau Of Personnel, and these two scientific organizations ended up together with the Office of Naval History . under the Deputy Chief of. Naval Operations for Administration. A look at this week's program reveals significant gaps in how other bureaus regard the ocean. Neither the bureau that is responsible for seaplanes, for example, nor the bureau that builds our docks and other underwater structures, appears to have anything to say on basic or 'applied- science in this medium. And a main complaint of the oceanographic contractors with the other bureaus and with the Office ? of Naval Research -- or so it appears to me -- is the intermittent way in which money for oceanography 55 ...**??Mbinea???????od Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED LYMAN UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 is ,turned off and on, so that long-term programs of investigation cannot be carried through. The result is that these contractors, the source of most of the country's trained oceanographers, are discouraging any expansion in training, and are turning to non-. military sources, such as the fishing industry, the IGY, and the great foundations, for their support. With a constant quantity of competent workers in the field expending an increasing effort on non-military work, we can only look forward to a decreasing total of work on military problems unless a firm policy is formulated at the top. What else do we need in military oceanography? Analysis of my two 'case histories of successful prediction operations shows that in both programs the key was the obtaining of the necessary data: In Arctic ice forecasting, existing systems for collecting data were inadequate and we were required to establish our own system of collecting and reporting. In ship routing, on the other hand, we required nothing but a few hours of office time, since the weather reporting and analysis system of the Weather Bureau was already at hand, along with the Pierson-Neumann-James (7) method of wave forecasting, and the key to their application to ship routing, the effect of waves on ship speed, was available through analyses of logbooks, where, in accordance with the dictates of prudent seamanship, watch officers had regularly and religiously recorded weather, course, and speed. These examples both pertain to surface conditions, where observations are made visually, and where experience at sea or in the Air is the. best training for an observer.. For underwater conditions, however, and where observations are made instrumentally, other types of observer training are needed: Far too many pieces of .naval underwater hardware are still being developed and tested under conditions where no '.attention is paid to the oCeanography Of the situation, and in environments such as Florida or the Caribbean that have no resemblance to the areas where they are most likely ultimately...to be used. The association of trained oceanographers with these testing programs would not only provide infprmation on the behavior of new hardware under varying ocean conditions, but would assist those responsible for the tests in choosing areas most suitable for the special requirements of tests, such as photography, aerial observation, underwater recovery, and.the like. UNCLASSIFIED 56 ?-5 LYMAN UNCLASSIFIED We need to recognize also that oceanic conditions vary-, and that the average picture may not necessarily resemble the instantaneous picture. For example, here is a portion of H. 0. Pub. No. 225, showing average ocean surface temperatures in the North Sea for December, and alongside it is a chart showing the actual temperatures for December 1956. One is the climatic average for the ocean -- the hydroclime; the other the synoptic picture of the water 7-- the hydropsis. The hydroclimic picture of the ocean is fairly well known, and the IGY will add a good 'deal, particularly in areas not well covered. For the hydroptic situation however, we still need to develop faster means of recording, reducing, storing, and, above all, recovering the data. One final requirement of military oceanography concerns reporting units. It will be observed that my two isothermal charts of the North Sea show different thermometer scales. In these cost-conscious days, military oceanography cannot afford the luxury of having part of its data -- that taken by the military establishment itself or by its direct contractors-- inBritish units, and part -- that taken by scientists working as scientists, and by its foreign friends -- in metric units. The sometimes appalling complications that result are too long to detail here, but I estimate that perhaps 25% of our total oceanographic effort is wasted in making conversions between the two systems, that training takes at least 50% longer and that the overall reliability of our products is reduced at least 10%. I am sorry to say that this .dichotomy was forced on the Navy not by the Navy itself but by .the scientists, stemming from a sacred cow attitude that simple seamen cannot be expected to understand complex units like meters, grams, or degrees Celsius:. This 'attitude sadly underrates the capabilities of the U. S. blue- jacket. If boots and midshipmen can learn to call the floor the deck and the drinking fountain the scuttlebutt, they can certainly master the simple system of measurement units that not only is part of the universal language of science but is. the everyday system throughout all the world except that speaking English. When we seek to standardize our naval operations, whether in NATO, _within the Western Hemisphere, or among the independent countries of Asia, we find ourselves out of step in our basic units. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 57 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LYMAN - UNCLASSIFIED ? Once an overall direction for military oceanography is established, one of its first moves should be to specify. that all observations of the marine environment be expressed in metric units. And the sooner we start. reckoning gunnery ranges in meters instead of yards, submarine depths in meters instead of feet, and oceanic soundings in meters instead of fathoms, the better off we will be. Changes are expensive, and they are always resisted, often merely because they involve something new; but even though this country can afford to consider occupying the moon, I maintain it cannot afford to continue the present wasteful system of duplicate units. In summary, the present requirements in military oceano- graphy are: I. An overall, coordinated program of investigating the sea. II. Expanded training of oceanographers. III. Close association of oceanographers with all phases of development and tests involving the ocean as an operating environment. IV. Development of data-collecting and handling systems to serve as the basis of predictions of conditions. V. Standardization on the metric system of units. LITERATURE CITATIONS 1._ SEIWELL, H. R., General remarks on problems of military oceanography, Trans. Amer. Geophys. Union, 24(1); 246-247, 1943. 2. *SEIWELL, H. R., Military oceanography in tactical operations of World War II, Trans. Amer..Geophys. Union, 27:' 677-681, 1946: 3. BATES,, C. C., H. KAMINSKI, and A. R. MOONEY, Development ' of the U. S. Navy's Ice Forecasting Service 194771953 and its geological implications, Trans: N. Y. Acad. Sci., 2(16): 162-174, 1954: 4. LYMAN, JOHN, The centennial of pressure-pattern navigation, Proc. U. S. Naval Inst., 74: 309-314, 1948. UNCLASSIFIED 58 ? LYMAN UNCLASSIFIED 5. SCHULE, J. J., and J. F. ROPEK, U. S. Navy Hydrographic Office synoptic and prognostic wave charts, H. 0. Tech. Rept. 16, 7 pp., 1955. 6. JAMES, R. W., Application of wave forecasts to marine navi- gation, H. 0. Spec. Pub. 1, 78 pp., 1957. 7. PIERSON, W. J., G. NEUMANN, and R. W. JAMES, Practical methods for observing and forecasting ocean waves, H. 0. Pub. No. 603, 284 pp., 1955. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 59 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LYMAN. ? UNCLASSIFIED I ?I 'AL. . ? . . . ? t i .?: .. . ? ! - ? )k. ??? . . - DEMURER 111% SURFACE HYDROPS1S itiownwv , ? ? . .:.. .. ? ? !r _, . ? Cr4. .syl,.: 1? , ,a _ ? IlliFtlir . .. IIlifip 111113111111111111111.11111151111a "Pilp ,).- illibiriEw .... igillitallii 00d0ros Ii 01111111101111114141.4.4rig "-.04i pio. ..-0...?........40, ?00.0.? ilp? wlvaitilsajoilli ., 111111111111111111111111111 111011111111111111 Ili 12 11111117 " Hi'DROGLIME klik. 60 0 tx0 UNCLASSIFIED 1 UNCLASSIFIED MAN ANDTHE UNDERSEA ENVIRONMENT L. G. Goff Navy Department . Office of Naval Research Washington 25, D. C. Whenever man's normal environment is appreciably altered, almost the entire range of his physiological and psychological functions becomes affected to a greater or lesser degree depending upon the individual and on the severity of such alteration. This is equally true of the young novice making his first underwater swim across a pool, the deep sea diver or underwater swimmer, submariner, aviator, or our anticipated space traveler. Whenever it becomes desirable or necessary that man extend his activities into extremely unfriendly environments, certain precautions must be taken and pro- visions made to ensure that he will remain alive and operationally efficient. With this kind of general approach there is no real di- chotomy of the environmental problem whether we are considering deep sea or deep space operations. There is only a broad environmental spectrum, a very limited portion of which' is i.eserved for man's normal existence. Certain regions of this spectrum contain factors which pose highly specialized problems but these do not severely influence the broad general problem of. maintaining man outside his assigned sphere.. ? The medical and biological sciences concerned with this . problem have not always been aware of the close relationship which exists among the various diyisionsof the environmental spectrum. . Aviation Medicinel,Diving and Submarine Medicine, Space Biology', and others have therefore evolved as highly specialized, and almost as highly -isolated, fields of endeavor. Recently there has been a growing *awareness within the Individual environmental specialties, of the similarity of their problems and of the possible mutual ? Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 6F. UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 forearfewpwal Goff UNCLASSIFIED benefits which could be derived from increased cooperation in the exchange of ideas and information. At the present time a serious attempt is being made by members of these groupsto effect a closer liaison and coordination. If full cooperation among all of the environmental specialists can be realized, the common problems will fall into their proper perspective and be resolved more quickly, leaving each group with only the special problems related to its sphere of interest. While the discussion which will follow is directed specifically toward the problem of man under the sea, it could, with only slight modification, apply to almost any adverse environmental condition. Man is essentially a land-dwelling, air-breathing mammal regulated to live between sea level and an altitude of approximately 15,000 feet and between the Arctic and Antarctic Circles. He is designed to walk most efficiently on two legs with his major axis perpendicular to his direction of locomotion, and must maintain a body temperature within a narrow range centered around 370 C. As a direct result of postural design, the most highly developed muscle masses of the body are the so-called anti-gravity muscles of the back and legs and the greater part of the total energy expenditure is used in maintaining an upright position and working against gravity. The undersea environment can best be characterized by a review of the unique properties of water shown in Table I. The first five of these properties are responsible for the fact that water is the one substance absolutely essential to all forms of living material. The high heat conductivity and capacity and the Table I: Unique Properties of Water 1. Highest Heat Conductivity 2. Highest Heat Capacity (except NH3) 3. Highest Latent Heat Of Evaporation t. Outstanding Powers as a Solvent 5. Exceptional Catalyst 6. High Surface Tension 7. High Dielectric Constant 8. *Optically Transparent 9. Efficient Conductor of Sound 10. Highly Incompressible 11.- Standard Reference for Fluid Density high latent heat of evaporation satisfy the necessary requirements in maintaining body temperature, the solvent action promotes dis- tribution of foods throughout the body and the elimination of wastes 62 UNCLASSIFIED - _ ? Goff UNCLASSIFIED and, the ionizing potential provides a catalytic medium in which metabolic processes can proceed at optimum rates. It is somewhat of a paradox that man should find that water is so ideally suited to his vital functions and yet, as a total environment, to be completely incompatible with life itself. In spite of this incompatibility man has chosen to invade the undersea environment as early as 2-3000 B.C. Excursions into the sea were for a-variety of reasons, not the least of which was for military advantage. The accomplishments of military divers, sub- marine forces, underwater demolition teams and small underwater swimmer attack groups have established beyond question the need for these activities in Naval operations. With the advent of the diving bell and the subsequent development of deep sea diving gear, submarines and, self-contained underwater breathing apparatus (SCUBA), water as an irrespirable Medium was no longer of primary importance. Underwater, as in any unfriendly surroundings, the problem is one of defining and main- taining an acceptable internal environment. The solution in each case will be unique to the individual man-machine system and its assigned mission. The individual swimmer or free diver represents the sim- plest and most versatile of underwater man-machine systems. Table II lists the activities in which divers and swimmers have established competence. While these tasks are now performed routinely and with Table II: Underwater Activities of Divers and Swimmers Peace and War Time War Time Salvage Inspection Damage Control Explosive Ordnance Disposal Underwater Demolitions Mine Recovery Bottom Surveys and Mapping Photography - Oceanographic Research Clearing Occupied Enemy Harbors Offensive Action Against Shipping Harbor Installations Other Shore Installations Cloak and Dagger Operations a high degree of success, very limited extension of these capabili- ties can be visualized from within our present frame of reference since man himself has become the major limiting factor in any con- sideration for increasing the depth, time or distance requirements. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 63 ? UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Goff UNCLASSIFIED Many phases of underwater swimmer activities can be ex- tended'by engineering developments' alone, but beyond a certain point, the end product becomes the submarine whose problem is, in itself, equally complex. It is therefore necessary that we obtain a complete picture of man and his relationship to his environment as a point of departure. The first problem is that of something to breathe. At the increased pressures encountered underWater any known respirable gas or gas' mixture has certain inadequacies beyond certain sharply de- fined depth-time relationships.- With air as the breathing medium, the normally high con- centration of nitrogen begins to exert a noticeable narcotic effect at 100 feet and progresses to the point of incapacitation beyond 300 feet.' In'addition to its narcotic action, nitrogen dissolves slowly in body tissues during a dive and sufficient time must be allowed for nitrogen washout during decompression if the depth time relationships shown by the bottom curve of Figure I are exceeded (1). In deep sea diving these phenomena are not a serious handicap since an inexhaustable supply of air is available and the depth-time schedule is under the control of a surface tendei. who prescribes the proper decompression procedure. SCUBA divers are not so tended and have only a limited air supply. They must therefore exert consider- able caution to avoid decompression sickness or "bends." Helium is used in deep sea diving to obviate the difficulty of nitrogen nar- cosis but it does not relieve the decompression requirement. Since the exact relationships between solution and washout of inert gases by the body are not sufficiently defined or understood, extrapolation of the helium deep diving decompression tables into the "SCUBA zone" or shorter-time, shallower-depth range is not feasible. Figure 1. Nitrogen non- decompression and oxy- gen tolerance diving limits for 55/45 nitrogen-oxygen mixture (diving depth ver- sus diving time). Drawn' from Figure 116, p. 233, NAVPERS 10838-A2. DIV/#6 /WPM (fad .r niaLt 041.411 (0T?01; //////// NITROGEN htlfI?DECOIWRISSION AND OXYGEN TOLERANCE DIVING LIMITS CAMUCriM zie.011133613 =VW ONINS OCVfl4 AND 1.4 Own OM 305 kb? riroultt CAYM TIN" *A Ct. 35% rilafity so. stitoNKILSA.c. .11reaLLA 00.1 - CttOMhA.t DIVING 17/If Gettams) 64 UNCLASSIFIED - ? ? :t4e, UNCLASSIFIED Goff One method of extending the depth-time capability is through the use of artificial gas mixtures such as a 45% 02-55% N2. The advantages of such a mixture is shown by the shaded area of Figure I. This technique however has certain limitations as indi- cated by the crossover point for nitrogen and oxygen limitations since oxygen itself becomes toxic at elevated partial pressures. It has also been observed that oxygen tends to become toxic at slightly lower partial pressures in the presence of nitrogen than when breathed as a pure gas. In spite of its high toxicity, pure oxygen has certain advantages in military operations. Since there is no waste, a con- siderably long gas supply can be carried, and with ample carbon dioxide removal, no exhaust bubbles are released and the equipment is quiet in operation. The limitations placed on the use of pure oxygen are shown in Table III. The mechanism of oxygen toxicity is not well defined and little is known about the quantitative effects of such factors as CO2 and exercise which shorten the safe exposure time. Table III (1) Depth-time limits for diving on 100 per cent oxygen Depth (feet) Time (minutes) 40 15 35 20 30 30 25 145 20 65 15 90 ? 10' 120 The oxygen requirements for work underwater are also. quite different from those for comparable work rates in air. Table IV shows a.rough_compression of values (1). At least a part of the increased requirement at rest may be attributable to a greater heat' loss in water and to an increase in muscle tone, however, the oxygen requirements in air and under water .for minimal exercise under iso- thermal conditions is not measurably different (2). At higher exer- cise_levels the increased oxygen consumption required for each additional increment of measurable work is exceptionally high. .,,This is evident from a comparison of drag data (3) (Figure II) with the oxygen consumption values of Table IV. Calculations show that' the Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 65 UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED UNCLASSIFIED N- - 11\ cc% cvl ? ? ? ? ? 0 \ 0 00 r--4 DRAG STUDIES OF SELF CONTAINED UNDERWATER BREATHING APPARATUS Cr\ CO IC\ '0 CO IA C-- Cr\ LA CO O\ Crl -.7 .-1 IA ? ? ? ? ? ? ? ? ? ? ? S ? ? ? CYI \JO Cr\ Crl LA --1' Cr \ 1-4 Cr \ (NJ . N- c?i 0 H H 2 3 4 5 SPEED, FT/SEC Figure .2. The exponential character of drag resistance curve as a function of water speed indicates the rapid rate at which any propulsion system will reach a limiting velocity. (1 ft/sec equal 0.68 mph) UNCIASSU'IED UNCLASSIFIED Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Goff UNCLASSIFIED work efficiency in underwater swimming is only about 5 per cent (3) as compared with 20-25 per cent for certain types of exercise in air (4). It is not clear at this time why oxygen consumption cannot reach the same maximum value in underwater work as in air regardless of the types or level of exercise performed. Table IV: Oxygen Requirements Basal - just "staying alive" Quiet sitting "Light" work - up to "moderate" work - up to ""Heavy" work - up to "Exhausting" work - up to Resting under water (just sitting quietly) 0.5 knot swimming (painfully slow) 0.85 knot swimming (about average) 1.2 knot swimming (too fast) 0.25 liters per min. 0.4 1.0 2.0 3.0 4.0 0.33 liters/min. 0.8 1.4 2.5 The comparatively high oxygen requirements and poor work efficiency have led to numerous suggestions that the mode of propul- sion of fishes should be studied in order to obtain a more efficient coupling of the human muscle masses to water. Table V is a summary of the speed of fishes as reported by Gray (5) and of man as reported by Passmore and Durnin (6). It appears that certain fish and aquatic mammals are able to perform at a maximum rate of approximately 30 times that of man. If only a small portion of this difference can be bridged, many operational advantages could be realized. The major advantages to increased water speed alone whether attained by man himself or through a mechanical aid would be the ability to operate against fast tides and currents or to shorten the time required to traverse a given distance. Increasing the range capability at'present would not be a great advantage where totally submerged navigation is required since the necessary navigational accuracy is not now available in equipment which can be satisfac- torily packaged for use by individual swimmers. There are Many problem areas in the field of individual underwater activities beyond those of a basic medical and physiolog- ical nature and of navigation. These include penetration of high turbidity, secure communications between individuals and with their parent craft, detection and identification of swimmers, underwater 68 UNCLASSIFIED 4 Goff UNCLASSIFED blast, deterrence and/or destruction, miscellaneous persdnal equip- ment, tools, etc. Most of these areas are more in the field of engineering than in biology and are therefore outside the scope of this discussion. However, no major daielopments should be under- taken without complete consideration of the other auxiliary-equip- ment, the mission and, especially the man who must carry out the contemplated operatioh. ' - A summary of the total problem related to adverse environ- ments in general indicates that operational capabilities are extremely short of immediate goals, because of the limitations of man himself. This Is largely the result of the recent rapid tech- nological advances which have produced such devices as deep bottom mines, the atomic submarine and artificial Earth satellites. Thus we have entered an era where man's capabilities and limitations, rather than those of the machine he operates, become the determining factor in the success or failure of operational missions. Prior to these recent major advances, increases in perfor- mance capability were realized in only very small increments. The operator, in this latter situation could be provided for by simple extension of existing techniques for environmental control. An entirely new approach to the problems involved in maintaining man in the underwater environment has to be considered now that opera- tional times and depths can be so greatly extended. The logical steps which must be taken are: (1) a complete understanding of man's normal environmental requirements, both physiological and psychological; (2) an adequate definition of an acceptable opera- tional environment; and (3) provision of the necessary instrumenta- tion for environmental measurement and control within the limits defined. The realization of these steps will be greatly accelerated when the various medical and biological disciplines concerned with environmental problems have effeeted the close liaison and coordina:- tion of effort now being attempted.: The ultimate goal of this com- bined group will be to'define and establish the environmental con- ditions which will permit man to conduct operations wherever and whenever the need arises and to maintain operational efficiency for the duration of any required mission. 69 UNCLASSIFIED n Has Ted in Part - Sanitized Copy Approved for Release 2013/08/02 CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 UNCLASSIFIED 61.1.10.4.apppyi Gof f REFERENCES Submarine Medicine Practice, Bureau of Naval Personnel Publication MAVPERS 10838-A, Government Printing Office, 1956 Goff, L. G., H. F. bruback, H. Specht and N. Smith, "Effect of Total Immersion at Various Temperatures on Oxygen Uptake at Rest and During Exercise," J. APPL. PHYSIOL., 9: 59-61, 1956 Goff, L. G.,H. F. Bruback and H. Specht, "Measurements of Respiratory Responses and Work Efficiency of Underwater Swimmers Utilizing Improved Instrumentation," J. APPL. PHYSIOL., 10: 197-202, 1957 Handbook of Respiratory Data in Aviation, National Research Council, Committee on Aviation Medicine. Report, 1944 Gray, Sir James, "How Fishes Swim," THE SCIENTIFIC AMERICAN, Vol. 197, No. 2: 48-54, August 1957 Passmore, P., and J. V. G. A. Durnin, "Human Energy Expenditure," PHYSIOLOGICAL BEVIES, 35: 801-840, October 1955 70- UNCLASSIFIED CONFIDENTIAL INFLUENCE OF OCEANOGRAPHIC ENVIRONMENT ON UNDERWATER DETECTION E. C. LaFond U. S. Navy Electronics Laboratory San Diego 52, California INTRODUCTION The influence of the oceanic environment on underwater detection becomes more important as sonar ranges are increased and greater emphasis is placed on target classification. Greater power in transducers alone cannot achieve the desired range and signal quality. We must also learn to use the transmission medium to our best advantage. This entails study of the underwater phenomena that cause attenuation, scattering, focusing, noise, and signal fluctuation. The purpose of this discussion is to review briefly some of the known environmental factors that affect sonar performance and to speculate on others based on .recent NEL studies. FAMILIAR ENVIRONMENTAL FACTORS Boundary Effects: the sea boundary effects are more ob- . vious than effects in the medium. The sea surface has been,ob- served to reflect and scatter sound depending. upon its rough- ness(1, 2, 3) and to generate ambient noise. (4) Likewise, 'the sea floor feature's are important in- the reflection, absorption, and , scattering of sound. (5) The acoustic effects depend upon the char- acteristics of the sea floor such as its roughness, grain size, porosity, density, elasticity, and depth of sediment. (6,7) Refraction: Probably the best-known acbuitic phenoMenon of the medium itself is that of refraction. (8) When sound enters a 71 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond CONFIDENTIAL thermocline or velocity gradient from above with a small downward angle, it is refracted with a decrease in.intensity at sone range be- low the gradient. (9) The returning echo is further attenuated by the effect of the thermocline, thus making detection unlikely in a shallow zone under strong negative gradients. This is sometimes referred to as a "bad sonar condition" or "bad gradient" (Figure 1). Figure 1. Lack of acoustic detection is frequently attributed to a "bad thermocline". Mine-hunting and even submarine -detection operations have been curtailed because of the severe refraction imposed by the thermocline: Even minute thermoclines or thermomicrostruc- tures give undesirable' effects. Sharp gradient's of only 0.10 centigrade can cause fluctuation of ,as much as 20 db in a vertical distance of only a foot or two when sound is transmitted at a low _ angle.. (1.0) . Scattering: Scattering is also known to reduce the sound level and ability of detection. In addition to the scattering that takes place at the sea's surface and floor, layers of scatterers and even globs or patches have been observed. The most common of 12 11, ) these is the deep-scattering layer. ( This layer is becoming operationally more important because 'of dee'per targets and because of the increased use being made of the sound-channeling principle, 72 CONFIDENTIAL LaFond CONFIDENTIAL ( which requires deep sound paths. (13, 14) Studies have shown that the deep-scattering layer undergoes diurnal migration and is most probably of biological origin. (15, 16) Shallow scatterers are also present,, especially on the thermocline. (17, 18) These turbid layers reduce both visual and acoustic detection. (19) As yet, few quantitative measurements have been made on the layers. Noise: Ambient noise affects acoustic detection. The sig- nal to be detected must be stronger or have a different characteris- tic than the background interference; consequently, a knowledge of ambient noise conditions is essential for assessing the detection potentials of a particular location at a particular time. It is known that ambient noise is a function of the wind speed or sea state. Many of the denizens generate characteristic, identifiable sounds. However, not all the unwanted sounds have been satisfactorily explained. (4) RECENT STUDIES OF ACOUSTIC VARIABILITY The known environmental factors by no means account for all the vagaries of underwater acoustics. Much of the sound fluctu- ation experienced in acoustic detection cannot be adequately explain- ed at the present time. (20, 21, 22, 23) Indeed, fluctuation has been referred to as "perhaps the most constant characteristic of sound in the sea. ,,(24) One notable example of acoustic fluctuation is that recently reported by Pinkston and others working in Chesapeake Bay. (25) Here, transmissions were. recorded of 100-kc sound over a path of 250 feet in shallow water. They showed large short-time fluctua- tions in signal strength. The coefficient of variation of the sound intensity was commonly as high as 0.5. Urick and Knauss, (26) also working in Chesapeake Bay, en- countered short-term fluctuations in acoustic intensity as well as gradual' fading of-the signal. ,The short-period fluctuations were attributed to microtemperature structure changes, but the cause of the fading was not clear. ,Many false targets, called "angels," appeared during these tests. These targets were believed to be fish. ?73 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Other examples of extreme variability have been reported by Garrison and Shaw in Dabob Har;(1?) by Sagar dff New Zealand;(27, 28) by Nanda in India; 29) and many others. Blackout: Probably the best example of acoustic variability is that of blackout. This acoustic phenomenon, reported by Carsola and others of this Laboratory, is a condition in which the signal is attenuated or scattered to the extent that there is a near or complete loss of return. (30) Blackout has frequently been noted off Mission Beach, San Diego, California, when using the AN/UQS-1 (100 kc' mine-hunting sonar) at a depth of 10 feet with bottom-mounted targets in about 60 feet of water. Here signal loss was observed for at least a few minutes during nearly every one of 20 days of operation spread over a period of nearly a year. The duration of reduced intensity was from less than a minute to nearly an hour. One extreme loss amount- ed to more than 80 db with the target 50 feet from the hydrophone. Many of the short blackout periods were preceded or accompanied by intense scattering lines. Another interesting feature was that black- out occurred more frequently at night than during the day. Although numerous unpredictable blackouts developed, only a few examples of the most distinct ones are compared with the water structure in Figures 2.A to E. For example on 11 February 1955 blackouts occurred periodically, some intermittent and others more consistent, for several minutes. These are compared with the temperature and turbidity structure over a 4-hour period in Figure. 2A. . At this time the water off Mission Beach had only a 2-degree Fahrenheit gradient from surface to bottom, yet numerous periodic blackouts were observed. Oscillations in the temperature structure are apparent,, with maximum displacement of the middle of the ther- mocline as much as 10 to 15 feet. Although; there is a slight rise in the thermocline there does not seem to be any abrupt changes in the water mass. The transparency too, from less frequent observations, is rather Constant with slightly more turbid water at the bottom dur- ing the blackout peridd. In another example, shown in Figure 2B, the only blackout -F-'?' . : 4.: ..-1 .... ,,..-. ), ? . 5, A 43. ? : =,- . sjwetz. . ;.-=.-..---. o ....% A -1 . ,.,- . ... ...... ,i. .... ,,.,...,,. _ .tr: ..'-'4- Agr- -7:56-1- F- ? 41% ' ... ...--- - --_ ? . ;W. ?,,.;,-*,.,t.....- z -,,,,,,....e.1,-- i.-,ag., e7r".7.,-,?-,...:-...,,ye.....?,. -,"- - &W.':;:.'"" 4 : . c?- ,s , . . ' ' 4 . .s. e71.4 4,-41, ?.., i\get. ' ?,".1 -4.-,w,? -4 -.?*,,:?.-77i,- . 7.-"".-'-. _ ,,,,s4:0-,0_,,,,,nq . , :?.,;.`: ....,?A -..i..- i''' . - i Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL 1930 LaFond 2000 2030 2100 HOURS 2130 Figure 2B. 'Comparison of the time of acoustic,blackout (represent- ed by a vertical. shaded band) with (A) the change of vertical temperature structure (?F) with time, and (B) the change of transparency (%) with time at the projec- tor-for two and one-half hours on 14 March in 60 feet of water off Mission Beach. 76 ? CONFIDENTIAL LaFond CONFIDENTIAL of the day (14 March) occurred between 2030 and 2045. The water transparency changed to a weaker gradient but the observations were made so infrequently that sharp changes were not apparent. The temperature recorded at 6 levels, ,on the other hand, showed a deep thermocline virtually on the bottom. Then 45 minutes prior to the blackout large vertical oscillations of the thermdcline took place. The isotherMs were displaced as much as 30 feet in 5 minutes. Four -giant wave-like oscillations occurred under thes receiving ship. Then came a period of total and partial blackout, followed by smaller thermocline oscillations at a higher level in the water. The water structure would indicate ?that both a vertical and a horizontal water. boundary with turbulence, at least in the form of vertical oscillations at the interface, was passing the ship at the time of blackout: Figure 2C shows other examples of the total and partial blackouts which occurred on 25 April. During the blackout period strong scattering lines were observed on the scope. The vertical motion as indicated by the temperature structure amounted to as much as 20 feet in only 60 feet of water. The entire thermocline appeared to rise and rather suddenly drop off, as if this section represented the boundary between two water masses. The turbidity also implies that the water at depth is more turbid after than before 2000, another suggestion of a change in water type. The temperature and transparency conditions for a 2-hour period on 20 June are shown in Figure 2D. On this day numerous blackouts were observed but only one distinct example is reproduced. It occurred at the same time that a giant internal wave passed the transducer. The abrupt.drop in the. thermocline was as much as 30 feet in 3 minutes. The following rise was nearly a's rapid. Subse- quent oscillations gradually became smaller. The limited.transpar- ency data taken during this 7-hour period indicate a reduced strati- fication of the water and a tendency of mixing- at the time of maximum waves. The' last example is a series of distinct blackouts which -occurred around midnight between 19 and 20 July, as shown in Figure 2E. Here the strong shallow thermocline was fairly constant until 2220 when the thermocline suddenly oscillated at a rate of as much as 10 feet per minute. Three 15-foot oscillations took place in succession followed by-oscillations at reduced'aniplitudes. ? The 77 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 ? CONFIDENTIAL I- -:0 . ? 2 '7 2 2 (/33d) H1d30 LaFond 78 2 7Id 5: 0 ? o 7.4 ?r1 ci)1 g1:1 0.) 4 > -1 4J.13 0 ct .2 ? al w ? )-c co 1:5 a) 'LI 4.4 0 0 0 Cr) MI k a) fa, Cu a) ? El) s4-4 ." C.) ? 0 4-1 O ? a) (1) 41) ? d ? k 5 a) u) > 0 cd 0 o -4 4_, En a) 4.1 ? tat) 0 k o 0 C14 Cd U" L.) 14-ECd EN3 o 4 g 0 o bO CONFIDENTIAL CONFIDENTIAL d700 10 20 30 40 50 1730 LaFond 1800 1830 HOURS 1909 10 5 30 - 40 50 60 80 85 85 Figure 2D. Comparison of the time of acoustic blackout (represent- ed by a vertical shaded band) with (A) the change of vertical temperature structure (?F) with time, and (B) the change of transparency (%) with time at the projec- tor for two hours on 20 June in 63 feet of, water off Mission Beach. 79 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL 2 0 0 0 o 1.3 (.1334) 141430 LaFond 80 0 0 0 ID 73, rig ft-4 (1) 1:11 ^ 13.) 0) (1) ;"I 4-3 453 al 1? 11) ?.? 4-4 a)^ ? 4) 11 0 Cd O ^ 0 ? 4' :??1 co tn a) ;-1 k .-cz ta.44 k 0 043) 73? 4 OL (1) r?%4 ;"4 4-, Cd p4 1:0 g ? " O4 ,54.3 ? 4.4 ? I:40 0 O 0 C.) Cd? ON Cd ? b0 43% ? Cd O A co ? u 0) 0 ^ .r4 (i) a) '5 0 " O 0 O cd 0 O 0 4.4 ? Cd (L) F-1 r4 0 1-1 tH Cd pi 4.4 7-1 0 rdrd 44, O A ? r4 CONFIDENTIAL LaFond CONFIDENTIAL the rmocline was 5 to 10 feet lower after the disturbance than before. The dense turbid layer became lower and less Concentrated after the burst of internal waves. Blackout has been observed only in the presence of internal waves. Many of the blackouts were accompanied by scattering lines; however, the presence of scattering lines did not always result in blackout. POSSIBLE ENVIRONMENTAL FACTORS , In view of the above-described phenomena, this Laboratory has been exploring possible causes of acoustic loss, including both familiar and little-known environmental factors. Among the latter are internal waves, bubbles, sea-surface slicks, and plankton. Internal Waves: One feature of the environment observed during all periods of blackout has been the presence of large vertical oscillations known as internal waves. (31, 34) Internal waves consist of complex vertical displacements of the isotherms which appear to travel at different speeds and with changing patterns. They have been observed in all oceans with wide ranges of periods and amplitudes. (33, 34) In the southern California area distinct internal waves have heights of 20 feet and a period which is frequently of the order of 10 - 15 minutes. However, many other shorter and longer periods are present. The waves have been observed to travel with speeds up to 0. 5 knot with wave lengths of about 20 - 240 yards. In several, instances off Mission Bea,ch, San Diego, the waves .moved shoreward while decreasing in amplitude. It is even conceivable that they may break, as indicated by occasional positive . temperature gradients: In any case the wave length and?pericid of internal waves are variable and more than one could easily occur in the normal mine hunting range. Thus, the absence of waves .at, the projector does not preclude their presence in the target field., The problem of refraction by internal...waves was -considered theoretically by assuming a typical three layer internal wave water- structure. (-55,36) From temperature data shown in Figure 2 a 81 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Cop Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond CONFIDENTIAL typical internal wave was considered having the following charac- teristics. Depth of Water 60 ft Depth of projector 10 ft Top layer (depth) 0 to 30-8 sinL._..rx (Av. 30 ft) where x = ' L range and L = 300 Middle layer (depth) 30-8 gi/i12E (Av. 30) to 40-9.1 ____ (Av. 40 ft) Bottom layer (depth)40-9.1 sin21rx Av. 40 to 60 feet Top layer (gradient) 0 ft/sec/ft Middle layer -4.8 ft/sec/ft Bottom layer -0.6 ft/sec/ft Wave length at interface 300 ft Beam pattern -10 db at ? 80 The interfaces of the thermocline are seen in Figure 3 to form two different sine curves. All acoustic ray paths passing through them are refracted by an amount which depends upon the angle of approach of the rays and the velocity discontinuity at each interface. For this particular problem the rays are considered to be traveling in a plane which is parallel to the direction of propaga- tioh of the infernal waves. Total reflection is assumed at the sea surfade and all sound energy reaching the bottom is, assumed to be' absorbed. This rep.resentation is an ideal situation, but it approxi- mates the natural sea. velocity structure more closely than any previously considered. Even in this ideal medium a great deal of computation was required for the multiple refractions and reflections ?ior'each 0.10 ray. This was nicely handled by the Electronic Computer Division of the Bureau of Ships. The detailed computation was carried on by means of the UNIVAC at DTMB. 82 CONFIDENTIAL LaFond CONFIDENTIAL -0 a) co ? cu a) ? a) E k 0 IX . cd 04 pi g I 0 It 0 r4 1 k ;-I 44 -8 8 I-45 It 0 0 4 1 9-I cd $3, ? ;.4 co bo k A 0 O g b.? ti) ? 0. PI ? 75 4-3 4 0 4.) ?, b? ... bo .... 0 4.1 i.- r:4 ? '-/ 0 cd .,.., u) -c ? ,-4 to 0 cd 0.) -a 'a rn 0 k k 0 OE! d 44 0 CO Pi .1. 4 e-I 4 U)o in trv 0 0 oe 0 ?.-1 cd cn o g k 0) k o 0) .2 Ti 0 Al "-i 0] .i O LI, 0 7:11 Ca o W .n ?r4 al t. :4-I a) CA 00 I I 0 0 MI TS 0 t? k - > 44 g indicated. o o LiI) 83 cr; C) 1333 NI Hi.d30bO CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 001Cr-Tel=g?Its LaFond CONFIDENTIAL Acoustic intensity of sound fpr each 10-foot interval of range and each 1 foot interval a depth were computed and contoured. The intensity at any point in the X, Z plane is based on an intensity of unity at one foot along a horizontal from the source. The values of the isolines have been multiplied by 106 to avoid very small numbers. Above the thermocline the sound intensity decreases with distance from the source. Below the thermocline refraction focuses the sound rays as they pass through the internal wave into alternate high and low intensity zones. The divergence and convergence of . the rays is directly related to the sinusoidal nature of the internal wave. In this example, there is one high and one low intensity zone for each interval of one wave length. The high-intensity zones become narrower with increasing range, whereas the low-intensity zones become wider. This variation with range is caused by waves near the source acting as a barrier for those farther away, i.e., fewer and fewer rays strike the waves farther and farther away from the source. Under similar situations of internal waves off Missions Beach the AN/UQS-1 gave a return signal in the form of a banded presentation on the scope, as shown in Figure 4A. The light portion represents stronger signals. Note that the bands near the projector are wider. Figure 4B shows another scope presentation with more detail. The indicated zones of high and low intensity are believed to be the result of the returning signal from sound focused on the sea floor at. that time. ? Targets are obscured in the high intensity zones and thus detection possibilities aie greatly reduced. These bands o'f high sound level, believed to be caused by _ internal waves, also 'decrease in intensity with distance from the - source due to spherical spreading of adjacent rays. Therefore the focusing effect of internal waves may be better demonstrated by anomalies in sound level which correct the previous computations for spherical spreading. These levels are expressed in db's; the refer- ence distance is 1 foot. 84 _ CONFIDENTIAL ? LaFond CONFIDENTIAL Figure 4. Examples of hands of .high and low pound intensity 'sh.own on the ?seOpe of AN/UQS-1 at, times of high internal 'via.Ves. 85 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond LaFond CONFIDENTIAL CONFIDENTIAL Figure 5 again demonstrates the zonal concentrations (with negative anomalies) which are caused-by sound focusing in internal waves and reflection from the surface. The tranSmission anomaly is expressed in db above and below the loss expected of normal spherical spreading. False targets are easily produced by such sound focusings. In nature moving internal waves of different sizes, as shown in Figures 2A through 2E, thus appear to be a major factor in acoustic detection by producing great variability in the return signal. Additional studies are underway.- ? Bubble Effects: Another environmental factor suSpe.cted of causing' acoustic variability' is small, even microscopic, bubbles. Laboratory stuaies indicate that gas bubbles can produce a great loss of sound energy if they are of the proper size in relation to the sound frequency. Fox, (37) for example, reported sound absorption due to gas bubbles about 0.11 mm in diameter to be as much as 30 db per cm at frequencies around 90 kc when the bubbles constituted only 0. 02% of the volume. These bubbles are visible; in fact experiments in the Laboratory and at sea indicate that divers can visually distin- guish individual bubbles as small as 0.06 mm in diameter. Iowever, under, normal conditions at sea no visible bubbles were observed to persist-in the water column. They rose towards the surface, increas- ed in size on reduction in pressure, and usually burst at the surface. Visible bubbles very near the sea's surface are caused principally by the entrainment of air from breaking waves. In addition to visual observation, they have been recorded during periods of high:winds with.a.N.K7 echo sounder mounted on the .bottom and directed upward in shallow Water: (38) Other-minor causes .of the formatiOn of bubbles in shallow water ate sea-floor as seepage, fish burps, and' decomposition of bottom detritus. (39'10) These 'visible.bubbles are all trarisient in nature., The best evidence of attenuation by still smaller, invisible, bubbles cs from Warner of NMDL. (41) He used the AN/PQS-1 in a tank with induced bubbles. After 'the water had cleared the sonar still could not receive echoes from the side of the tank only 5 feet away. This condition lasted for two hours. From this significant discovery it appears that invisible gas bubbles can persist and cause attenuation for long periods of eime. It is at least theoretically possible that such long-lived invisible bubbles exist beneath the sea CONFIDENTIAL CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Bubble Production: .'0.ne approach to the problem of bubble generation is throug4 the study.?Of the-oxY'gen saturation of the water. Oxygen' concentration at,vaiious depths and its relation to tempera- ture struCture and water transparency were investigated off Mission Beach. The oxygen content of thewater in summer was found to be maximtiMbelmv the surface and above the densest turbid layer in all cases, as shown in Figure 6. However, when the per cent satu- ration was- determined for in situ conditions, that is, when the solu- bility Wag- corrected for pressure, temperature, and salinity, the vertical saturation cur'ves differed from the oxygen content curves. Figure ,6. Vertical distribution of dissolved oxygen (content m1/14, saturation of oxygen., (%). The Calculations for in situ conations, assuming nitrogen saturation at all levels, showed that the Upper 12 to 14,feet were supersaturated_ with oxygen.. The maximum supersaturation, which occurred at the surface, ranged from 120 to 148%. This high oxygen. layer, probably derived from photosynthesis of plant organisms, occurred on the upper side of the layer. The increased light at the shallower depths- LaFond CONFIDENTIAL facilitates a higher rate of photosynthesis, and therefore a greater potential oxygen production at this level. Unusually high oxygen content is not surprising under condi- tions of high phytoplankton production. For example, during periods of high plankton blooms the waters near San Diego were observed to have an oxygen saturation as high as 200 per cent. (43) Pickard(44) reports that oxygen in the waters of the British Columbia inlets may be supersaturated as high as 170 per cent due to .the action of large concentrations of phytoplankton. The significant thing is that supersaturation of water samples can be reduced by shaking, indicat- ing the instability of the oxygen in the water. Under high supersaturation conditions, a small bubble introduced either by organisms in the water column or from the surface may actually grow. However, these bubbles will tend to rise at increasing speed and be lost at the surface. Thus, per- sistence of these bubbles over long periods of time cannot be ex- pected, unless either some mechanism exists for keeping them submerged or there is a source at depth. One possibility is that the particles responsible for the high turbidity of the water might attach themselves to extremely fine bubbles, thereby preventing or retarding their rise to the surface. Another possibility is that bubbles may continually or periodically generate in the water column. The action of internal waves is still another mechanism by which oxygen bubbles may be produced. If supersaturated or nearly supersaturated water is brought up from one depth to a lesser depth the per cent saturation increases.- The vertical displacement may amount to at least 30feet as demonstrated by the height of the observed internal waves. Similar. changes in pressure on oxygen- saturated water caused it to release bubble in laboratory experi- ments which were performed in a pressure 'chamber by bubbling oxygen through water," releasing the pressure, and noting the forma- ' tion of bubbles. In addition to the reduced pressure on the crest of internal waves there is usually some turbulence associated with the therm.o- -cline as indicated by the visual distortion of objects when viewed through it, and the distortion of the vertical colored path made by dye marker when dropped through the water. (45) It is believed 89 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond ' CONFIDENTIAL possible' that this tuTbulence and the reduced pressure caused by dominant internal waves are of sufficient influence on supersaturated water to free some of the oxygen and other gases in the form of small bubbles-in- the sea. Slicks: Several observers have indicated a strong correla- tion lietween the presence of slicks (glassy patches or lines on a rippled sea) and fluctuations in acoustic transmission and detec- tion. (46,47) Acoustic echoes are frequently obtained from water near slick lines. Sound transmitted toward some slick zone ? is sometimes completely absorbed or scattered, thus producing an acoustic barrier. 'Also unusually high readings are obtained on the AN/UQQ-1 wake (bubble) indicator when it is towed through a slick. (48) Many types of slicks are developed in oceans, lakes, and harbors. (49, ()) (Figure 7). They result from the various water motions, wakes of ships, and local wind-induced motion. They may also result from contaminants, such as fresh water, organic material, oil, and foam concentrated as a thin film at the surface. (39) The concentration of contaminants in the San Diego region takes place primarily as a result of convergent motion set up by internal waves. Hence, slicks may provide a visual indication of the presence of internal waves. The thermal structure of the water associated with slicks was investigated. With BTs and towed thermistors it was found that the surface water temperature in slicks was higher than the tempera- ture between slicks by an average of 0. 3? F in?April and 2.0? F in August, with a maximum of 2. 8?F. Assuming that higher tempera- tures are found at the immediate surface in spring and summer, this, result would indicate that the immediate surface waters were moving toward and'concenfratin.g in the slick bands. (50,51) The .oxygen and other gas saturation was found to be highest at the surface. Under a heating of 2?F the saturation of all gases will increase and some of the gas may be forced out of solution in 13ecause of the high organic concentration', the bubbles thus fcirmed can persist at the surface as foam. In some slicks during quiet weather, bubbles have been seen to suddenly emerge from the water, temporarily remain at the surface; and then burst. These 90 CONFIDENTIAL '4 Tigiire 7. Sea surface slicks. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond LaFond CONFIDENTIAL CONFIDENTIAL apparently are derived from the heating- of gas-saturated water. The vertical and horizontal temperature structure normal to slicks is shown in Figure 8. Note that the isotherms are de- pressed under nearly all of the slicks, and this depression may be as much as 30 feet. . SURFACE ? SLICKS It 03 FEET 2500 Figure 8. Relation of sea surface slicks and internal waves off Mission Beach. The transparency of the water near slicks was also examined by towing a hydrophotometer at a constant depth under a series of slicks. Unusually high-turbidity zones were encountered under the slicks, is' shown. in Figure 9. In the relatively clear water between slicks about '60 to 70 per cent of the light was trans- mitted through a meter i)ath, 'whereas under the slicks only 10 to 40 per cent was transmitted. These turbidity zones appear to be the result of surface convergence in the slicks. The material causing the tp.rbidity zones near the surface was,foundto be mainly organic. Some turbid Water caused by plankton Populations develops in situ. Other turbid water appears to originate frozn the shallow nea.rshore region. Net hauls and '- diver-collected samples of the material causing a shallow turbid layei? were analyzed and found to be phyto and zooplankton alive and in varying stages of decomposition. RFACE SLICKS I )_ ii.. 4 \ ....... a Al V . , f c. 0 ' " 1 . j$ J ,. ?. .?, ..., _ Figure 9. Relation of sea surface slicks and water transparency at 6 feet depth off Mission Beach. Plankton: The ability of plankton to attenuate or scatter sound in turbid zones and in the open sea has not been definitely established. However, new evidence indicates a relationship between the seasonal cycle of reverberation and the presence of plankton. The production of plankton is not uniform throughout the year. In the nearshore southern California area the greatest pro- duction is in the spring. (52) This probably also holds true for the offshore regions, where acoustic scattering measurements have been made from 1953 - 55. (53' 54) During the early Lorad studies the reverberation was measured for the entire annulus of the ,.first 30 mile convergence zone., These data were plotted in Figure' 10 by Mackenzie. (55) When the seasonal trend of this acoustkO measure- ments is cornpared with the seasOnal trend of plankton production for previous* years there is a rea.sonable agreement. This would suggest a correlation between plankton in the sea and the higher reverberation observed in spring. Thus, plankton may be, one of the many environmental factors which affect acoustic detection. The preceding discussions point out various features of the environment which may affect detection. The problem, then, is to find ways and means of overcoming adverse environmental factors CONFIDENTIAL CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL LaFond SO 'NO I 101.10301:Id 11101VICI 3A 1.1V131:1 (i) Li- `C-11:1Z) 13A31 NOI .1..V1:1391:13A31:1 1VNOZ 94 "") CONFIDENTIAL LaFond CONFIDENTIAL so as to realize fully sonar equipment capabilities. UTILIZING THE ENVIRONMENT The possibility exists of modifying the oceanic environment so that it becomes more suitable for acoustic detection. In harbors or limited areas this may be appropriate. However, in the more strategic open sea, techniques of making these changes are still obscure. The more likely solution is to use equipment where it will utilize the environment to best advantage. Variable Depth Sonar: One example of using the environ- ment to best advantage is by the variable depth principle. By lower- ing a transducer below a marked thermocline (or velocity gradient) the range and probability of detection are greatly increased. (56) When the sound source and the target are below the thermocline, the -refraction between the transducer and target is reduced. In fact, certain areas may be intensified by sound focusing above that, of the normal spherical spreading of rays. Under these conditions, the thermocline may be a help rather than a hindrance in acoustic detec- tion by VDS (Figure 11). 3 Figure 11. Avoiding the "bad thermocline" effects by use of YDS detection equipment. 95 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 The VDS not only combats the adverse velocity profiles but effects a decrease in grazing angle. When the sound rays strike the bottom at lower grazing angles the scattering coefficients are reduced. (57) The greater receiver depth aids detection because of the lower background noise level due to greater separation from the surface and ship noises. Even variability of temperature, salinity, and resulting refraction is reduced below the thermocline. Also, the effects of near-surface phenomena such as air content of water And micro-organisms are minimized. It is evident that the. VDS ? effectively utilizes the environment to better advantage that the similar conventional hull-mounted gear. Topography: For longer ranges topographic features can be utilized. Greatest ranges are attained when the sound makes the fewest reflections from the surface and bottom. This require the least spreading of the rays and the deepest water. A desirable topography for long-range detection is a relatively steep continental slope and a flat reflecting floor. Each desired detection site must be surveyed for velocity structure and detailed topography. Off the San Diego area a suitable detection site would be near the bottom on the edge of the continental slope. Under the usual downward refrac- tion in this region a direct-ray insonified zone could be produced which would bend down the slope, reflect from the bottom once, and retain sufficient energy to return a signal from a target located at or neai the surface another 9 miles further out. Thus, the selection of proper environmental sites for detection equipments can materially increase detection ranges. ?Sound Channels: For still longer ranges in deep water the channeling .of sound energy by the refractive structure of the water can be utilized'. Here the physical properties of .the water column , . that control the sound velocity become increasingly important. The vertical band of sound .r.ays leaving a shallow sound source are re- fracted downward by the permanent thermocline. Near the bottom the soprid rays are refracted upward by thelhigher pressure and to some extent by the increased salinity at great depths. The band of sound Kays reappears in annular zones near the surface at a dis- tance of about 27-33 miles in the Pacific (Figure 12). Sound transmission studies have shown that such cycles are repeated out to several-hundred miles. (58) With suitable high-power, 96 CONFIDENTIAL 61 LaFond CONFIDENTIAL ANNULAR IN3ONMED 2014ES SOUND.,L, VELOCI.TY RANGE IN RULES, ? 2010 , z?; Figure 12. Utilization of sound velocity structure for sound channeling and longer detection ranges. low-frequency active sonar such as Lorad, detection of targets in bands at ranges of about 30, 60, and 90 miles has been achieved. (59) Topographic highs, if they protrude into the insonified zones, will obstruct the sound path and restrict the detection range. (60) This method of utilizing the environment has resulted in reception of echoes from submarines at ranges over ten times as great as with conventional sonars. When both the sound source and receiver are at a depth near the axis of minimum velocitrin the deep sound channel, one-way "SofaK" transmission ranges of thousands of miles 62 61, ) have been achieved. ( Near-surface channeling of sound rays is also possible when the proper velocity structure is present and the surface is relatively smooth. (63) ? Deep Water:. Still another technique is to operate detection equipment at great depths where the background levels are very low and therefore detection potentials are greater. The bathys'caPh or , similar deep submersible could be-adapted for this purpose. Sound Velocity: A precise knowledge. of sound velocity would 97 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond CONFIDENTIAL make it possible to determine accurately long sonar ranges. Accu- rate range information is necessary if a dis.tant submarine is to be attacked by an air missile or if the loCation of water entry of a missile at Very long range is to be determined. Generally, sound velocity has been computed by theoretical methods using ancient informatfon on the physical properties of water. (64, 65,-66) However, some. recent measurements have been made to determine .the average velocity over a long path and compare this with precise oceano- graphic measurements. (67) Other Possible Means: This discussion has dealt largely with sonar detection. Other methods of detection may use the electrical, magnetic, or pressure fields set up in the water. Changes in environment detectable by infrared means or ionic 68) changes in the ocean may be possible. (There niust be still other properties of the sea which are not yet investigated which would make a suitable indicator of detection. SUMMARY In summary, there are many components in the oceanic environment that affect detection. As yet, from an acoustical stand- point only refraction and some scattering properties of the medium are known to any degree. In many instances, the causes of fluctua- tion in acoustic detection cannot be adequately explained on the basis of present knowledge. This points up the need for extensive funda- mental studies of processes in the ocean. Some. possible environmental factors affecting acoustic fluctuation and detection are speculated to be (1) refraction in internal waves, (2) the presence of minute bubbles in the sea, (3) the near-surface boundary effects associated with sea surface slicks and (4) plankton. Further investigations of these subjects should take into account the detailed spacial distribution.of watei. properties., the re- lationship of the many oceanographic variables to each other, and short-period time fluctuations.. The knowledge thus gained should allow acoustic conditions to be predicted and the oceanic environ- ment used to fullest advantage. 98 CONFIDENTIAL 410 LaFond CONFIDENTIAL REFERENCES 1. Navy Electronics Laboratory Internal Technical Memorandum 112, Correction of Hydroacoustic Output Measurements for Effects of Surface Reflection Under Specific Refractive Con- ditions, by F. A. Dahm, (Unpublished), 15 Nov. 1953. 2. Urick, R. J., "The Processes of Sound Scattering at the Ocean Surface and Bottom", Journal of Marine Research, v. 15, . no. 2, p. 134-148, 1956: 3. Pennsylvania State University Ordnance Research Laboratory - Serial NOrd. 16597-24, Sound Back-Scattering in the Ocean at 25 and 60 kc, by R. M.. Hoover and F. E. Kaprocki, ?CONFIDENTIAL, 15 Mar. 1957. 4. Navy Electronics Laboratory Report 486, A Survey of Contem- porary Information on Underwater Ambient Noise, by F. A. Dahm, CONFIDENTIAL, 23 April 1954. 5. Office of Naval Research, A Summary of Underwater Acoustic Data, Part 4: Reverberation, by R. J. Urick and A. W. Pryce, CONFIDENTIAL, February 1954. 6. Hamilton, E. L. and others, "Acoustic and Other Physical Properties of Shallow-Water Sediments off San Diego", Acoustical Society of America. Journal, v. 28, no. 1, p. 1-15, 1956. 7. Navy Electronics Laboratory Report 803, from Shallow Water Bottoms at 2. 8, W. E. Batzler, M. D. Ward, and J. . DENTLAL, 13 August 1957. ? Acoustic Scattering 5. 5 and 8. 0 )cc: , by A. Whitney, CONFI- 8. National Defense Research Committee- Division 6 Summary Technical Report v. 6A, The Application of Oceanography to Subsurface Warfare, p. 1-103, 1946. 9. Naval Air Development Center NADC-WR-5710, Oceanographic Factors of Major Importance in Submarine Detection, by L. Y. Shakt, p. 1-24, CONFIDENTIAL, June 1957. 99 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 _ - ? LaFoncl. CONFIDENTIAL 10. Washington University Applied Physics Laboratory APL/UW/TE/55-50, Oceanographic Investigation; Report of Measurements for One-Year Period Ending 1 Nov. 1955, Project 10,. by G. R. Garrison and J. T. Shaw, 8 Apr. 1957. 11. Raitt, R. W. , "Sound Scatterers in the Sea", Journal of Marine Research, v. 7, no. 3, p. 393-409, 1948. 12. Johnson, H. R. and others, "Suspended Echo-Sounder and Camera Studies of Mid-Water Sound Scatterers, " Deep Sea Research, v. ,3, no. 4, p. 266-272, 1955/56. 13. .Scri,pps _Institution of Oceanography Marine Physical Laboratory S. I. 0. Reference 53-36, Wide Band Sound Scattering in the Deep Scattering Layer, by V. C. Anderson, 1953. 14. Hersey, J. B., and others "Recent Findings About the Deep Scattering Layer," Journal of Marine Research, v. 11, no. 1, p. 1-18, 1952. 15. Navy Electronics Laboratory Report 334, Sonar Studies of the Deep Scattering Layer in the North Pacific, by W. E. Batzler and E. C. Westerfield, 8 Jan. 1953. 16. Johnson, M. W., "Sound As a Tool in Marine Ecology", Journal of Marine Research, v. 7, no. 3, p. 443-458. 17. Trout, G. C. and others, "Recent Echo Sounder Studies", Nature No. 4315, v., 170, P. 71-72, 12 July 1952. 18. LaVond, E..C. and D. W. Pritchard, !'Physical Oceanographic Investigations in the Eastern Bering and Chukchi Seas Dur- ing the Summer of 1947", Journal of Marine Research, , v.. 11; no. 1, p. 69-86, 1952. 19. .Burd, A. C. and A. J. Lee, "The Sonic Scattering Layer in the . Sea", Nature NO. 4251, v.. 167, p. 624-626, 21 April 1951. 100 4 CONFIDENTIAL 4 LaFond CONFIDENTIAL 20. Pennsylvania State University Ordnance Research Laboratory, TM 7. 3366-35, Recent Acoustic Observations of a Near- Surface Layer of Scatterers in the Sea, by R. J. Urick, CONFIDENTIAL, 23 April 1956. 21. Canada Pacific Naval Laboratory Interim Report PIR-7 The Fluctuation of Sound Transmitted in the Ocean, by R. W. Stewart, H. L. Grant, W. N. English and C. D. Maunsell, 1 August 1955. 22. Naval Mine Countermeasures Station Data Report 5415 (GD-5)15, Statistical Analysis of the Effect of Oceanographic Variables on the Probability of Detection of Ground Mines by the AN/SQS-15 Variable Depth Sonar, by J. N. Boyd, CONFIDENTIAL, 22 June 1954. 23. Texas University Defense Research Laboratory Report DRL-A-79, Analysis of Tape Recordings Made During the Evaluation of the XHB Mine Hunting Sonar, by L. A. Jeffress, CONFIDENTIAL, 19 July 1954. 24. National Research Council Committee on Undersea Warfare Serial NRC:CUW:0027, Basic Problems of Underwater Acoustics Research, Chapter 7: Fluctuations of Sound in the Sea, by C. Eckart and R. R. Carhart, CONFIDENTIAL, 1 Sept. 1948. 25. Chesapeake Bay Institute Reference 57-6, Sound Fluctuations and Related Oceanographic Parameters in an Estuary, by E. R. Pinkston, ?M. J. Pollak, and J. R. Smithson, September 1957.. 26. Naval Research Laboratory Report 4530, A Descriptive Study of the Acoustic Fading of Mine Targets, by R. J. Urick and J. A. Knauss, CONFIDENTIAL, 5 May 1955. 27. Sagar, F. H., "Fluctuations in Intensity .of Short Pulses of ? , 14. 5-kc Sound Received?from a Source in the. Sea"; Acoustical Society of America. Journal, v. 27, p. 1092- 1106, 1955. 101 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 ? Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond CONFIDENTIAL 28. Sagar, F. H., "Comparison of Experimental Underwater Acoustic Intensities of Frequency 14.5 kc With Values Computed for Selected Thermal Conditions in the Sea", Acoustical Society of America. Journal, v. 29, p. 948- 965, 1957. 29. Nanda, J. N., "On Origin of Fluctuations of Sound Trans- missions in the Sea", Indian Journal of Meteorology and Geophysics, v. 8, no. 3, p. 325-328, 1957. 30. Navy Electronics Laboratory Report 785, Some Major Environ- mental Factors Affecting AN/UQS-1B Sonar Performance, by A. J. Carsola, R. F. Dill, G. P. Schumacher and H. W. Volberg, CONFIDENTIAL, 10 June 1957. 31. Sverdrup, H. U. and others, The Oceans, Prentice-Hall, p. 585-602, 1942. 32. Ufford, C. W., "The Theory of Internal Waves", American Geophysical Union. Transactions, v. 28, no. 1, p. 96-101, 1947. 33. Ufford, C. W., "Internal Waves in the Ocean", American Geophysical Union. Transactions, v. 28, no. 1, p. 79-86, 1947. 34. Ufford, C. W., "Internal Waves Measured at Three Stations", American Geophysical Union. Transactions, v. 28, no. 1, p. 87-9.5,. 1947. 35. Navy Electronics Laboratory Technical Report 760, -An Example of Sound,LRay Focusing by Internal Waves, by C. R. Sparger, 'CONFIDENTIAL, 25 January 1957. - 36. Lee, Owen S., Sound Focusing by Internal Waves, (Manuscript)..' 37. Fox, F. E. and others, "Phase Velocity. and Absorption Mea- surements in Water Containing Air Bubbles," Acoustical Society of America. Journal, v.- 27, no. 3, p. 534-539, 1955. CONFIDENTIAL 102 . 4,? 'LaF.ond CONFIDENTIAL 38. Morse, L. L., Effect of Wind on Attenuation of 14 kc Sound in Shallow Water (Manuscript). 39. Navy Electronics Laboratoni Report 828, Slicks and Related Physical Properties of Near-Shore Waters, by R. F. Dill and E. C. LaFond, CONFIDENTIAL, (In press). 40. Navy Electronics Laboratory Technical Memo. 259, Do Invisible Bubbles Exist in the Sea?, by E. C.? LaFond and R. F. Dill, 4 September 1957. 41. Naval Mine Defense Laboratory Technical Paper No. TP111, A Report of Blackout of the AN/PQS-1 Diver's Hand,-Held Sonar, by H. L. Warner, CONFIDENTIAL, July 1957. 42. Ramsey, W. L., Dissolved Oxygen in Sweetwater Lake and Near-Shore Waters of San Diego, California. (Manuscript). 43. Nusbaum, I., (Personal Communication), California Water and Pollution Board. 44. Canada. Fisheries Research Board of Canada Progress Re- ports of the Pacific Coast Stations Issue No. 99, Oceano- graphy of British Columbia Mainland Inlets, Part IV: Dissolved Oxygen Distribution, by G. L. Pickard, p. 9-11, July 1954. 45. Navy Electronics Laboratory Technical Memorandum 203, . "Shimmering", The Visual Distortion of Objects Underwater at Thermal Boundaries, by R. F. Dill, 1.8 Sept. 1956. 46. Navy Electronics LabOratory Report 151, High-power short- - pulse echo -ranging, by L. R. Padberg, CONFIDENTIAL, 24- March 1950. 47. Navy Electronics Laboratory Report 476; High-Power Short- Pulse Eeho-Ranging Sonar, by' L. R. padberg and. F. D. Parker, .CONFIDENTIAL, 19 April 1954. ? - 103 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond CONFIDENTIAL 48. University of California, Marine Physical Laboratory, Towed Hydrophone-Model 2, Revised Preliminary Operating In- structions, Revision 1, CONFIDENTIAL, 1 Dec. 1950. 49. Ewing, G., "Slicks, Surface Films and Internal Waves", Journal of Marine Research, v. 9, no. 3, p. 161-187, 1950. 50. ? Dietz, R. S. and E. C. LaFond, "Natural Slicks on the Ocean," Journal of Marine Research, v. 9, no. 2, p. 69-76, 1950. 51. LaFond, E. C., "Factors Affecting Vertical Temperature Gradients in the Upper Layers of the Sea", Scientific Monthly, v. 78, no. 4, p. 243-253, April 1954. 52. Ricketts, Edward F. and Jack Calvin, Between Pacific Tides, 3rd ed., p. 345-374, Stanford University Press, 1952. 53. 'Navy Electronics Laboratory Technical Memorandum 110, Spectrum Studies of Sonar Reverberation From Surface Convergence (LORAD) Zones, by E. C. Westerfield, K. V. Mackenzie, M. K. Brandon, J. A. Whitney and N. S. Young, CONFIDENTIAL, 23 May 1955. 54. Navy Electronics Laboratory Report 698, LORAD Summary Report, Lorad Reverberations Part II, Article 6, by K. V. Mackenzie, p. 1142-1161, CONFIDENTIAL, 22 June 1956. 55. Mackenzie, K. V., "Seasonal Variation of LORAD Reverberation and a Possible Correlation with Phytoplankton-Production", U. S. Navy Journal of Underwater.Acoustics, CONFIDENTIAL, (Manuscript). 56. Naval Mine Countermeasures Station Data Report 5417(GD-5)- . 16, Probability of Detection During the Norfolk Variable Depth So.nar Test, by H. P. Williams and J. N. Boyd, CONFIDENTIAL, 20 August 1954. 57. Navy Electronics Laboratory Technical Report 554, Sonar Echo and Bottom Reverberation Studies Related to the 104 CONFIDENTIAL LaFond CONFIDENTIAL Mine Countermeasures Program, by W. E. Batzler, C. A. Turner and M. D. Ward, CONFIDE/4TIAL, 24 Nov. 1954. 58.. Navy Electronics Laboratory Report 559, Results of a Long- Range 530-cps Underwater Sound Transmission Experiment, . by M. A. Pedersen, E. R. Anderson, J. F. Kidd, and R. M. Lesser, CONFIDENTIAL, 17 January 1955. 59. Hale, F. E., "Results of Recent LORAD Tests". Presented at the 15th Navy Symposium on Underwater Acoustics 28-30 October 1957, CONFIDENTIAL. 60. Saur, J. F. T., and H. W. Menard, "On the Probability of ? Successful Convergence Zone Transmission Over an Irregular Sea Floor", U. S. Navy Journal of Underwater Acoustics, v. 4, no. 4, p. 99-114, CONFIDENTIAL, October 1954. 61. Anderson, E. R. "Distribution of Sound Velocity in a Section of Eastern North Pacific," American Geophysical Union Transactions, v. 31, no. 2, p. 221-228, April 1950. 62. Navy Electronics Laboratory Report 175, Sofar Research Group, 1950. Triangulation tests of the northeast Pacific Sofar network, UNCLASSIFIED. 63. Navy Underwater Sound Laboratory Technical Memorandum 1110-56-56, Propagation of Acoustic Waves ip Surface Sound Channels, 0.1-5 kc: Part 1, by M. R. Powers., 30 June 1956. - 64. Kuwahara, Susumu, "Velocity. of Sound in Sea Water and Calcu- lation of the Velocity for Use. in Sonic Sounding", Hydrographic Review, v. .16, no. 2, p. 123-140, 1939. 65. Beyer, R. T., "Formulas for Sound Velocity in Sea Water", JOUrnal of Marine Research, v. 13, p. 113-121, 1954. 66. Naval Research Laboratory Report 4002, The Velocity of Sound ? Iii Sea Water at Zero Depth, by V. A. Del Grosso, 11 June 1952. 105 ,CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 LaFond CONFIDENTIAL 67. Mackenzie, K. V., Formulae for the Computation of Sound Velocity in Sea Water, (Manuscript). 68., Navy Electronics Laboratory Technical Memorandum 249, Can a Deep Running Nuclear Submarine be Detected by Infrared?, by Karl F. Herzfeld, CONFIDENTIAL, p. 1-10, 12 June 1957. 106 CONFIDENTIAL COINFIDENTIAL MICROSTRUCTURE OF THE OCEAN AS IT RELATES TO THE TRANSUSSION OF ULLDFitWATER SOUND D. S. Potter Applied Physics Laboratory, University of Washington Seattle, Washington INTRODUCTION The purpose of this paper is to discuss some of the limitations imposed on the applications of underwater acoustics by the presence of small inhomogeneities in the volume of the sea. Although the in- homogeneities 'are extremely small and result in sound velocity changes of the order of 1/100 of 1%, the continuing action of these "scat- terers" over long ranges results in large anomalies in sound propaga- tion. In sound transmission, the effect of these inhomogeneities can yield a large fluctuation in signal intensity, as well as a "wander- ing" of the direction of sound energy propagation. Similar inhomo- geneities in the earth's atmosphere have shown the feasibility of long-range, high-frequency radio transmissions which extend well beyond the normal limits imposed by the earth's curvature. A great deal of effort, of course, has been expended in radio and radar studies of the effect of .atmospheric and tropospheric "scatterers". So, too, in the acoustic field, problems' of this general character have received increasing attention since World Aar II. In spite of this activity, from the designer's point of view, _? the information currently available, on both the occurrence of such inhomogeneities in the oceans and the detailed effeet on acoustical transmission is only now .beginning to be understood._ Hence, there has been little attempt to take such factors into account' in the design of underwater weapons systems. In the' period immediately 'following World War II, considerable attention was paid to the problem of fluctuating' sound levels. ocean measurements there are, of course-, many easily found reasons n rlassf ed in Part - Sanitized Copy Approved for Release 2013/08/02 CIA-RDP81-01043R002200220009-0 107 CONFIDENT TAL Potter CONFIDENTIAL Declassified in Part - Sanitized Copy Ap?roved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 for the production of flucttating levels - interference from the sur- face boundary, ship motion producing a misorientation of transducer patterns, etc. - which explain the bulk of these early observations. However, when careful experiments are performed which eliminate, insofar as possible, all of these obvious causes, there still remain9 a fluctuation in intensity wnich finally must be attributed to the 'medium itself. At about the same time, it was noticed that small temperature deviations were present in the ocean. .There was a great deal of hope that these temperature deviations might, in the final analysis, be responsible for the residual hard core of intensity fluctuation, which had to this point found no other explanation. For example, an early paper of P. G. Bergmann (1) in 1946 -develops tne theory of scattering of sound energy in a random inhomo- geneous medium in the ray limit. jbcperimental work was carried out by Sheehy (2) in which he made direct measurements of the intensity fluctuation in direct transmission between two deep transducers. In addition, Liebermann (3) made a series of measurements in 1951 of the temperature deviations of the sea, using a submarine cruising hori- zontally at constant depth as a platform. In 1953 and 1954, Mintzer (4,5,6) published a series of papers concerning sound scattering in a statistical medium much as Bergmann envisioned, except that Mint- zerts work was done in the wave limit of acoustic propagation. In, a later paper by Potter and Murphy (7), the solution of the scattering problem for a particular statistical distribution, valid in both the ray and wave limits, was obtained. This work was entirely concerned with sound scattering in a medium which could be described on the basis of a fairly simple statistical modelli More recent work reported by Skudrzyk (8) of gem has extended the statistical model to the case of a medium exhibiting Kolmogorov turbulence. Tne statistical model is an attractive one from both the theoretical and expetimental points of view, since it reduces -a tremendously complioated structure to a few simple parameters which now describe only the average properties of the medium. However, like all, statistical averaging processes, simplicity is purchased at the'expense of eliminating knowledge of what occurs over short times. Thus, for an acoustic experiment lasting for a short enough time, the statistical model gives little information. In the language of statistical mechanics, the question is, "What time is required to assure the application . of an argotic hypothesis?" Although, in some instances, .the direct acoustic experiments have tended to support the theoretical conclusions on the basis of . the various statistical models, there have been some notable failures, which lead one to the inevitable conclusion that, because of the various diverse mechanisms responsible for-temperature changes and acoustic fluctuations, there are, in fact, several quite-different models which must be employed. 108 CONFIDENTIAL Potter CONFIDENTIAL DESCRIFTION OF MICROSTRUCTURE The term "thermal microstructure" must be defined.. In the great bulk of thermal observations made in these% the .fundamental instru- ment has been the batnytnermographl Which records temperature to about 1/20 F as a function of water depth. Hence, for present pur- poses, we will define thermal microstructure as temperature structure occurring in the volume of the sea whose deviations from the immedi- ately surrounding water are of the order of a few hundredths of a degree Centigrade.. The Statistical Model The statistical model used in most of these studies follows very closely the one developed by Liebermann on the basis of a series of measurements of the temperature deviations made on cruises in the coastal waters of the Pacific Ocean from San Diego to Alaska. The resulting record Of the temperature deviation from the average as a function of horizontal displacement was random in appearance, and gave support to a statistical model of the thermal microstructure of the medium. It turns out that the medium may be described suffi- ciently well for fluctuation calculations on the basis of two para- meters, if one i willing to make certain assumptions. The first parameter is the spatial autocorrelation of the temperature deviations. This is a measure of tne intuitive nation that the deviation from the mean temperature at two points in tne water which are close together mould be expected to be about the same, while temperature deviations at widely separated points would be expected to bear little relation- ship to each other. The distance, "a", over which such correlations exist was found to be about 60 am in the horizontal direction for this data. The second parameter, the root-mean-square deviation of the temperature from the average, is. a statistical measure of the magni- tude of the deviations.. The experimental value for this parameter was about 6.05? C which whenconverted to the sound velocity change, was of the order of 10. The existence of a correlation distance nas resulted in a tend- ency to think of the temperature deviations as if they. were "patches" of warmer or colder water. These patches naturally have, an ill- defined shape, and no true boundary exists between one "patch" and another on the basis of tnis viewpoint. 'A sophistication of this model?is achieved by allowing the correlation distance in the hori- zontal and vertical directions to be different. It is, of course, necessary to establish the correlation function, but, except for back-scattering, its form, is not critical. _ Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 109 CONFIDEMEIAL Potter CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 The Layered Model As a result of an extensive study of the thermal structure and acoustic properties of Dabob Bay and the waters of Puget Sound by the Applied Physics Laboratory, a very different model was found necessary for describing the thermal microstructure of this area. In substance, the findings were as follows: DEPTH, FEET NEW HIGH-SENSITIVITY THERMISTOR PROBE 8.4 8.6 8.8 9.0 9.2 TEMPERATURE, ?C BATH 0TH ERM PROFILE 9.4 7 8 9 10 11 Figure 1. A Comparison Between the High?Sensitivity Probe and a Bathythermograph. First, it was necessary to gain some idea of the detailed tem? perature structure not shown on bathythermograph readings. Figure 1 showa aoomparison.between two different instruments for recording . temperature as a function of depth. The curve shown: on the left was obtained utilizing a. temperature probe with resolution better than 06010 C. The extreme temperature range covered by this Profile is 1 C; the bumps-and wiggles, which are readily resolved, are of the order of a few hundredths of a degree C. The corresponding bathy? thermograph profile drawn to its usual scale is ShOW11 on the right. Thnslan absolutetemperature measurement as a function of depth, akin to a bathythermograph record but sensitive now to 0.010 CI revealed the existence of horizontal thermal layers. Within each layer, the temperature deviatedl in general, from that of the water immediately_ above and below by about 0.1? C or less. The vertical 110 CONFIDENTIAL Potter . CONFIDENTIAL thickness of these layers varies from a few feet to tens of feet. The most remarkable characteristics of this layered structure are the horizontal extent of the layers and their time stability. Ektensive measurements in Dabob Bay show that such layers extend for hundreds of yards in the horizontal direction with the vertical temperature distribution substantially unchanged. We also find that such struc? ture is, in general, very stable with time, remaining for many days once it is formed. Thus, we are led to an oceanographic model for - N BUOY 20 YDS N .40 YDS N 60 YDS. N 80 YDS N 100 YDS N 120 YDS N 140 YDS N TIME 1100 1108 1116 1124 1132 1140 1148 1156 ' 50 41 100 LiU. I- 0. Li 0 150 200 8.40 8 45 8 40 845 8.40 845 84Q 8.45 8.40 8.45 8408.45 8.40 845 8.40 8.41, TEMPERATURE, CC Figure 2. Variation in Temperature Profile Over a Distance of 140 Yards. this region wnich treats the tnermal microstructure as strictly horizontal layers extending througnout the transmission region. The evidence supporting the layered model as being representative of the actual conditions existing in Puget Sound and in some areas of the North Pacific Ocean appears to be convincing. The spatial extent of promontories on the temperature vs. depth plot can readily be seen in figure 2. The eight measurements snown in this figara were spaced 20 yards apart, covering a total distance of 140 yards. The impressive thing here is the fact that-the promontories are clearly defined and are recognizable across this entire distance. As can be seen, there is a tendency for the shape of the temperature profile to cnange with distance. Since the eight measurements'invoIved were made consecutively, tne time variations must also be considered. Figure 3. is the result of a series of measurements carried out at one location. This loca? tion was fixed by mooring to a buoy in Dabob Bay. The temperature' drops, which were made every five minutes, give an excellent history CONFIDENTIAL Declassified in Part- Sanitized Copy Approved forRelease2013/08/02 : CIA-RDP81-01043R002200220009-0 111 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: CIA-RDP81-01043R002200220009-0 Potter Potter CONFIDENTIAL CONFIDENTIAL of tne changing profile with time. There is some gross water motion in Dabob Bay because of the tidally excited seiches, whicn account for,the gradual change in depth of some of the promontories. It is naturally very difficult to obtain such Measurements in the open ocean, where mooring buoys are'not available. However, some temper- ature-depth curves taken off the coast of Alaska, unfortunately at widely separated stations, bear a remarkable resemblance to those found where layering is known to exist. Five of these are shown in figure 4. TIME: I133 1138 1143 1148 1153 1158 1203 1208 1213 1218 1223 1228 1233 1231112431244 1253 1254 250 ma r. 300? X 1303 1308 1313 1318 1323 1328 1333 1338 1343 1348 1353 13581403 1408 1413 1418 1423 1428 The formation of layers of water has been studied quite exten- sively and is somewhat better. understood. The major requirement for the production of such anomalies is the following: Imagine two large bodies of water which join at a common interface. Imagine that one body of water has a temperature and salinity distribution which gives rise to a monotonically increasing density wttn increasing depth (necessary. for equilibrium). Now, if the second body of water is o- 100- 200- TEMPERATURE,?C 5 6 6 7 6 7 7 8 8 9 I DA808 BAY 3 AUGUST 1855 Figure 3. Change of Temperature Profile with Time. FORMATI0N OF MICROSTRUCTURE The formation of a thermal microstructure following a statisti- cal model is quite difficult to understand unless one has available large energy sources for the continued'formationtsuoh as would be available in a shoaling area off a coast. The reason for this is tnat the patches of water quickly dissipate unless they are in equil- ibrium. .Skudrzyk has.proposed an interesting mechanism for the con- tinued generation of patches, whereby the required energy is avail- ' able because of the induced turbulence Of the shoaling water. CONFIDENT-IAL 500- 600- 700- 800- NO. 38 63 MI. FROM SITKA I APR 1957 0200 NO. 39 334 MI. 4 APR 1957 1030 NO. 41 368 MI. 4 APR 1957 1550 NO. 42 485 MI 5 APR 1957 0940 NO. 43 575 MI. 5 APR 1957 1640 Figure 4. Temperature Structure in the Ocean 20 Miles off the West Coast. essentially isosaline and isothermal, and if its density is equal to- tnat of the first body of water at some depth, then there will be an exchange of water between the two bodies of water. The intrusion of water from one zone to another produces large eddy currents, and,these eventually appear as long, tnin layers of . water, different in temperature and salinity from the surrounding water. The end requirement of a monotonic density distribution, essentially independent in a horizontal direction is, of course, comp- plied with, since tne. process is only stopped when mecna4cal equi- librium is reacned. If tie density profiles are not so idealizedl CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 ? CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 ?vcol?'?1\ NW` . sk:???????? ...... ....... ? . ? ? .... . . . ... .. .... ... ......... . . ?????? :s ? .... ;;/' 111111011 . f 111111111R111111111F 1111111111111111111111111111111111111111 8.5 -9.0 ?C 111.1 SURFACE TEMP 14-16?C 17 MAY 1957 NORTH BUOY TGT BUOY. SO. TOWER TSKUTSKO OAK HEAD FISH HAZEL PT PT HBR /M 10.0-10,5?C 10 5 -11 0?C WEE OVER 110?C TGT BUOY SO. TOWER TSKUTSIKO OAK HEAD FISH HBR. HAZEL P. 1,11111iiiitomon Ilia .ll11111111111111111111010111111111111111111110 11110mh "' .......................... 1910" IllelM111111 ql lotto% \\\\ 11144 7.0-7.5?C 1779 7.5 -8.0?C* kaid 8.0-8.5?C 8.5-9.0?C 9.0 -9.5?C MEM 9.510:0?C ? . M110.0 -10.5 ? C 1111110.5 -11.0?C SIMI OVER 11.0?C Figure 5. Isothermal Diagrams Showing Initial Stages of Flushing. then there will be many layers formed. The dynamic process is quite rapid when compared with the thermal process; hence,- the assumption of such an interface leads to a stable, layered water structure. 7 0 - 7 5 ?C 7,5 -8 0?C EF,I?A 8 0 - 8 5?C E121 8 5-9 0?C 9 0-9 5?C MI 9 ,5 -10 0?C ?Mj 10.0-.10 5?C :10.5-11.0?C ME 11.0 -II 5?C TGT. BUOY SO.TOWER. TSKUTSKO PT. OAK HEAD FISH. HBR. HAZEL PT ? Figure 6. Isothermal Diagrams Showing Final ' Stages of Flushing. The. formation of layers in Dabob Bay is well illustrated by the isothermal diagrams for Dabob Bay and HoOd Canal shown .in'figu.res 5 and 6. The first diagram of figure 5 is a late spririg- Condition _- which, in general, gives a monotonically decreasing temperature , CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 OONFIDiNTIAt Potter Declassified in Part-Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 profile. The -isurfabe,mater,marms,,considerably in midsummer. 3.n. Hood Canal;; there is sufficient turbulence: caused by the .'1argetidal'act4on so that the, -.7rater:3,1fiecomes-,--.*611::iixed",eridNherice warmed ?throughi*t::. Acrose;',tlieiriterface? between.HOOdf Canal irids Dabob Bay there are' now large liorizondensiti-gradie.i:Its:, The Hood Canal water intrudes into Dabobi.Hay:;:asi,erio*i in figure 6, and, even _op the?coarse,scale of these figures, produces a:well,,defined? layering ,',effect. V?iher,i;.:e)0211- hied irr','-detaili,..3,it,'"4:6',:fo4nd::tnat:4,neie 3.4sr.*!4 are from a few feet tens of:::,..feetrltnick;'..and::,c4-044.17i1Yfei'e seV`eral.::hundred.';.yards..-ins.s.hari- zontal extent;-thei teurPeratUre` differenae;:beingfa'-few::Iiiindiedths of a degree Centrigrade.`"?-lir',thefirst' few jiOntiii, the ttiin layers seem to to fade away, leaving a residue - Of 'rather. thick..:rayers. At the'end of six months, the layering is considerably redliced, and at this time the process is? repeated; except that in the winter the intruding layers are coldert,han the existing water. One of the outstanding features of this layered structure is the remarkable time stability of the structure. Once formed, such layers are in static equilibrium and, in the absence of sources of large mechanical energy - e.g., currents produced by waves - they remain in position. .The,mechanism ,remaining for .dissipation is thermal ,conduc- tivity. ',"?-KOrr!,I4erk'br'-Patche'S'':Cff'S4:;Size (a yard. Or more:, in extent) the the prO`des-e'?:,.8for:clirip.ry.- heat condu.ction is very slow. Calculations show f,fia a'year 'or more .may be required before the temperature fferende becomes immeasurable. ? ?-- One might speculate that a_mechanism.,,equivalent to that in .Dabob Bay is present in the open 'ocean. Thiscould be the intrusion of water at the interfaCe, oft. an Ocean .current = with the remaining water. This local production of anomalies in riot, be..?yell defined, since the ocean currents are?imown to limeander"..quite':)51t, thus producing anomalies over a wide expanse. This; coupled with the- long inherent life of the large layers, could cause a generally widespread. occur- rence of such anomalies. Some ocean measurenierits have been ina:de.:by this Laboratory,, as ',well as other groups, and strong evidenCe of layering has been found oft the Alaskan coast, off Oregon, and in the San Diego area. Unfortunately, there :is almost no information avail- able in any other area and, except for.Puget_Scund, the present data is too meager to permit any analysis. EFFECT ON SOUND TRANSMISSION- A J???9,.. ??? ? ,.? , Of all of the effects which the thermal microstructure of the medium has on ,acoustic transmission, the most extensively studied has .been4that of intensity fluctuation. Figure 7 ?ShOys.,..1,he experimental arrangement 'employed lay A?r, in Studyingithis pnenonenbri. In these ' measurements, an acoustic' tran?itter witru a unif'orm-azimuthal'pattern, CONFIDENTIAL' 116 CONFIDENTIAL 100 ? ? 400 500 TEMPERATURE ? C 7.5 80 85 Potter 100 400 500 60 600 Figure 7. Experimental Arrangement for Sound Transmission Measurements. SOUND LEVEL 1-1 10 DB Tr> is lowered to a convenient water depth. A receiving hydrophone, also with a uniform pattern in tne horizontal plane, is used to probe the sound intensity of the directly received pulse as a function of depth. A fairly typical intensity-depth profile is shown on the right of this figure. As can be seen, intensity fluctuations can be in excess of 10 db. Figure 8 snows a fairly typical set of intensity-depth *pro- files taken at varying ranges from approximately 80 to 500' yards. These measurements were made in Dabob Bay in the presence of a layer approximately 20 feet thick having a temperature change of 0.10 C. ? One finds that the primary intensity fluctuations are concentrated at - approximately the depth of the layer. The depth of the transmitter is indicated on the figure by T. If the medium exhibits essentially statistical properties, it is only possible to determine statistical properties. of the intensity fluctuations. However, in the layered model it is tempting to try to calculate this intensity variation. Such a calculation is -readily made in the ray limit. Figures 9 and 10 are two examples of such a carculation,.obtained utilizing a ray perturbation calculation applied to the actual Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 117 -CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Potter Potter CONFIDENTIAL CONFIDENTIAL RANGE, YDS II 109 137 175 210 310 423 491 TIME 1150 1200 1206 1211 1229 1245 1252 ACTUAL SOUND LEVEL ..... cACTUAL CURVE 200 ............ :"."::. APPROXIMATION FORMED BY A SERIES OF GAUSSIANS PREDICTED SOUND LEVEL TEMPERATURE 1--I ' 0.I?G SOUND LEVEL 250 Ui Ui a. Ui 300- SOUND LEVEL I---1 5DB DABOB BAY 17 MAR 1955 5 AUG 1955 DABOB BAY RANGE 520 YDS - Tx DEPTH 240 FT Figure 8. Effect of Temperature Layer on Sound Transmission at Several Ranges. I I 8.5 8.6 8.7 TEMPERATURE, ?C SOUND LEVEL ---0PREDICTED There is a great deal of data on intensity fluctuation, but it ACTUAL is probably sufficient merely to note that this is a well established effect of the tnermal microstructure, and .that the present theories - are able to account in large measure for the magnitude ob?erved. It is unfortunate that these measurements have been carried out in only a few selected areas and that little in a quantitative. may is known about this effect in the open ocean. Figure 10. Comparison of Measured Sound Level Profile with Predicted Profile. temperature profile. The experimentally measured sound level is shown along with the calculated profile. As can be seen, this type of calculation does predict both the magnitude and general trend in sound intensity., but by its very nature, of course, it cannot account for the rapid fluctuations. Although the magnitude of fluctuation is seen to be in excess of 20 db in one of these examples, this is a rather extreme case for such a short range (520 yards). ' Pigure 9. Comparison of Measured Sound Level Profile with Predicted Profile. In the design for current and future weapon systems, the problem of bearing wander of sonar information is at least equal in import? ance to that of intensity fluctuation. In this area, however, very little has been done. Several calculations nave been made concerning the magnitude of the bearing wander due to a thermal microstructure CONFIDENHAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part-Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL 0- 100 300- 400- TEMPERATURE 1.0?C Potter RANGE 350 YDS TARGET SIZE, DB 10 DB Tgt 0 START OF SUCCESSFUL ATTACK A START OF UNSUCCESSFUL ATTACK L LOSS OF TARGET rI 100 200 300 400 500 RANGE, YARDS DABOB BAY SEPTEMBER 8, 1955 Figure U. Effect of Temperature Layer on Performance of Mark 143 Torpedo. under the assumption of a statistical model, although very little has appeared in the published literature. Because of the long ranges at whicn such an effect becomes important; it is no longer profitable to .consider the idealized layered model given earlier. This comes about because tne layers are probably between 3.00 and 1000 -yards in extent, well less than interesting sonar ranges today. This model ? can be handled as a rather bizarre case of a statistical model in which the vertical 'and horizontal correlation differences differ by a factor of approximately 100. The only direct experimental measure- ment of this important effect was, made recently at the Naval Under- water Sound Laboratory. The preliminary results neither agree nor disagree with previous theoretical calculations. This unfortunate situation arises rather naturally because of the almost complete lack of information concerning the properties of the ocean in the test area. Based on the best available information, tne bearing wander can be expected to be of the order of 1/2? at 10,000 yards, 120. CONF3DENTIAL Potter CONFIDENTIAL rising to perhaps 1o at 401000 yards, at least in those Select areaSo;-? ? of -the ocean where information is available: ? ' ? ? ; EFFECT ON WEAPON :PERFORMANCE The single case in which weapon pei?formanee Was degraded -by- the -? thermal microstructure of the medium was observed with Mark 143 tor- pedoes in Dabob Bay. In tnis case, the torpedoes failed 'to hdme -on a ?simutated acoustic target because of the loss, of ebhd?Signal: loss of tartet, termed an aborted attack.? occurs primarily at the': time of year when a strdng layering situation- exists iir-the bay: The' Mark 143 torpedo has a vertically stabilized transducer, and for this- '? reason can tell only if- it is above or below the .target. Because' its normal homing trajectory is such -as- to bring it to target depth -as ? rapidly as possible,- it, usually arrives at target- depths at ranges excess of 200 yards.- As indicated earlier, the intensity fluctuation- caused by a layered -structure will be at a maximum when-both trans, mitter and receiver are in the immediate 'area of:the layer. -The acoustic "holes" .arisingifrom the layers were-found to be directly responsible for the aborted attacks. In order to demonstrate tnis point; the following experiment was run: A- temperature measurement' was made in the operating' area, and from this a target depth was- chosen which was predicted to give aborted attacks. Figure 11 shows the result of this experiment. The temperature profile is -shown - oil' the left. The center curve is the profile of the equivalent acoustic' target size. The predicted acoustic "hole" at a depth of 200 feet - is seen to have a magnitude of almost 10 db at a range of 350 yards.' The trajectories of four torpedoes are shown at the right. As can be seen, in every.case the torpedo lost the target on its first pass. This problem became so acute that it was necessary to provide-the ' torpedo station with acoustic services during this critical period so that proofing could be continued. Although tnis is the only sub- stantiated case of weapon degradation arising from the thermal micro- structure, there have undoubtedly been many-other unrecognized pro- blems. ,The implications to future weapon systems of the acoustic pro - blems'discussed in this paper are fairly obvious-butl-becauselofthe-.z- lack,of.:detailed information, the proper-remedial action-LS-not''So - obvious. The fluctuation-in intensity results, .of cbursel in lost , information. .The amount of information whicn is lost, and the manner1:1 of-loss, depends-upon the magnitude of-the fliictUation and aide On the mechanism. If one Considers .only the statiStical model; the -flue.= t,uation from ping to ping' ofan active Sonar system is randOnf (assuming some motion of the submarine) and, as a result, one can readily calculate the .,statistical quantities which have hearing-on the problem. These will include tne net information rate, -the probability of losing two or more consecutive pieces of information, and so on. 121 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Potter,. CONFDDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 With tne assumption of a _random process, the method of analysis for.. optimum weapon performance is. available and can be utilized. On the other hand, if, as seems more likelY, the open ocean tends more nearly to the layered model, then the problem is greatly complicated. ,In, this cases the high spatial correlation of the fluctuations (in the horizontal direction) means _that the loss, of one ping makes the pro- bability of the loss of several, additional pings high. It is as if there mere ."dead zones"..in.the water. The requirements on the remainder of-the system are then made much more difficult, since in,- formation maybe lost tor relatively long periods. If it turns out that the .Layer-type problem?ip_bf,major,poncern, then a quite soph- isticated.systemrwill be required .to give a reasonable operability. Similarly,,the effect on, fire control sonar mill be more serious for the layered model. The possibility of losing .contact with the target, for fractions of a minute may rule-out-certain weapon systems, or may call for an.even;more Sophisticated missile. Weapons are now failing to perform bedause of information loss, and with the necessity for, , increased homing ranges, a major cnange. in homing philosophy willbe required before satisfactory. performance is obtained. Such a change would be in the direction of providing a better "memory"; then, when homing information is, lost, the torpedo can continue Along, a most . probable course instead of breaking off ,the attack and returning to a searchphase. Naturally, .additional _functions which must be per- formed by the missile make tne system more liable to equipment mal-"- function. As viewed from the overall system viempoint, it may be. desirable not to ask_more.of the missile, but to require more from the., launching vessel, where human judgment is available. ?? . The problem hof fire control errors can receive no more than a superficial treatment at this point, since.the fundamental data con- cerning-bearing errors is not available. In principle, however, there are several basic weapon systems, differing in communication require- ments between launcher and missile, which can avoid some of the pro- blems connected with fire controkerror. . - The weapon system making the most severe requirement on the fire. control data is the 'classical predicted intercept weapon,, In. such a System, tne target motion is' presumed to be known and a predicted, intercept point is caldulated,-taking into account tne travel time of- the weapon. The %r9ri_dlYar II torpedo ,firing system is, of course, an exdellentexample of tnis.- At relativeiy short ranges, this weapon system is very effective, but as the, range increases, the pro- bability of success is greatly diminished. The .principal reasons ' for the decrease in performance are:: . ? .(1),: increased error in.the target motion; which leads to 6.. ? ? , ? 122 CONFIDENTIAL Potter CONFIDENTIAL (2) increased error of predicted intercept position, which, in . . turn; leads to. (3) larger error in weapon delivery, and . (4) increased flight time, which makes evasive'maneuvers very effective. The most obvious way of regaining a nigh hit probability is to. ? increase the radius of ethality of the warhead, either by adding homing or a special warhead. This change is effective' for non-evading targets at ranges up to about 10,000 yards, but beyond that point it loses effectiveness because of the fire control errors of present sonar systems. The next step may be made in eitner-df,twO-directiOnsi decrease tne flight time of the Missile or communicate with it to give in-flight corrections. The decrease in flight time is extremely ? effective at' shorterranges, but beyond 10,000 yards it appears that it will still be necessary to predict the target course. It is not possible to estimate tne effective range with the added feature of predicted intercept; however, with present sonar accuracies, and with an evading, high-speed target, the upper limit of useful range may be considerably less than 20,000 yards. In addition to ail of the data concerning the missile characteristics, it will be necessary to know the minimum errors in the fire control sonar system before eval- uating the potential of this weapon system. Anotner alternative, in-flight correction to tne missile, is beset with similar difficulties, and to these must be added the additional complication of a prolonged loss of information at a cri- tical time. Information loss, although disturbing in the other sys- tems, is not critical, since the firing time can be delayed until adequate information is available; however, if in-flight correction is necessary, then adequate information during the flight is most important. Additional weapon functions ma Y readily 'be imagined, 'each de- -signed to overcome some failing, but each, ,because of the increased complexity, tends to lower tne reliability. The above situations serve to illustrate the cnoices:whicn must be made.' The choice of. decreased flight time versus in-flight corrections will depend to a great extent upon the probability of obtaining adequate fire don- trol information: For the short-travel-time missile, the'require- merit is 4gh accuracy, witn information loss being allowable; for the correctable missile, the major requirement is continuous infor- mation, witn less accuracy allowable. ? coNauslaas In considering the effect of thermal inhomogeneities on both acoustic, weapons and fire control sonar, it has been impossible to Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 ? -'123 CONFIDENTIAL . 01:11.M.10L-40.., ft* ? CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Potter ? state with real assurance, what the limitations are, except to say that trielimitations most certainly exist. :The almost complete- lack of experimental data on tne aspects of the temperature structure of the ocean, that..a.Fenimportent in tnis problem, plus the. absence of a'tneory of 'bearing erio'r, ineane that no 'autnoritative statement of tne real effect on our weapons and weapon systems can be given. In the long- range underwater _missile program,. it now appears that the virtually unexplored fie1d of sonar bearirig error will 'assume great importance because .of the *Pact of tnis one parameter on weapon system per7. 'farmer:ice. .pan be seen, .,the present 'state of Imowledge is quite ina.de-.. quate toT answer the pressing question,, of the syst.ein designers. Enough..explo. ratory work nap been done, however, to show the nature of tne problem, and to offer guidance for a thoroughgoing research effort.- 124 ? CONFEOENT ? CONFIDENTIAL Potter REFERENCES . 1. P. G. Bergmann, Phys. Rev. 1.2, 486 (1946)._ , 2. M. J. Sheeny, J. Acoust. Soc. Am. 22, 214. (1950). 3. Leonard Liebermann, J. Acoust.. Soc. Am. 311 563 ( 1951). 14. D. Mintzer, J. Acoust. Soc. Am. 25 822 (1953). 5. D. Mintzer, J. Acoust. Soc. Am. 25 1107 (1953). 6. D. Mintzer, J. Acoust. Soc. Am. 26 186 (19514)? 7. D. S. Potter and S. R. Murphy, J. Acoust. Soc. Am.-12, 197 (1957). 8. Eigen Sku.drzyk, J. Acoust. Soc. Am. 29, 1124 (1957).. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 ? CIA-RDP81-01043R002200220009-0 125 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL THE PAST, .PRESENT AND FUTURE OF UNDERWATER CLASSIFICATION A. J. HILLER U. S. Naval ReseaTch Laboratory Washington, D. C. Where have we been; where are we how, and where are ? we.going.in the field of sonar classification? The following covers t1 highlights on these questions and show the several paths which may be taken that offer the most promise in polving the. problem at hand. First a little background. Statistics obtained from World War II data and more recent frustrations during ASDEVEX ex- ercises emphasized the existence of a real problem. From one viewpoint the inability to determine, with a high degree of accuracy, whether or not an underwater object is submarine or non-submarine causes problems in logistics and tactical diversion. A classificaticn systexn of low accuracy leaves sufficient doubt as to the immediate threat of a possible submarine. that the general doctrine was to shcct anyway. This combined with the general ineffectiveness of ASW weapons resulted in .a high weapon expenditure on many contacts of which few were real submarines .and resulted in an early logistic shortage of weapons. Today, however, with the increased threat of the sub- marine considered in mOre gross terms such. as the exchange of coastal cities and industrial complexes for the lack of a successful detection and kill, one may consider again the shoot first philosophy. Such circumstances require that the accuracy of classification need not be high. In summary we see that the degree of solution of the 126 CONFIDENTIAL. ? W.; Hiller CONFIDENTIAL classification problem required is closely interwoven with consider- ations of weapons and economics. However, since it has been shown that consistent high ac- curacy of classification has not been possible in the past, a Classi- cal scientific problem did (and still does) exist, and is therefore a challenge deserving of an intensive research effort. The term. "consistent high accuracy" is quoted since there have been and still are situations where evidence indicates it is achieved. These are the cases of the selected few experienced sonarmen who seem to have a mysterious sixth sense which en- ables them to sort out the subtle characteristics of a submarine by aural methods. Thus one concludes that a general solution is to find out how the classification mechanism of the human mind works. It also appears that the sonar signal may contain sufficient infor- mation which, if properly analyzed and presented, could in itself result in satisfactory classification. Under the leadership of the Bureau of Ships, the classi- fication problem was tackled on a broad front. In addition to the Bureau laboratories, the U. S. Naval Research Laboratory and numerous University groups under contract were coordinated through a classification committee. The approach taken was classi- cal - to first obtain data on submarine and non-submarine contacts from which differences, no matter how subtle, could be measured and studied. Several extensive classification cruises were planned and organized by the U. S. Navy Underwater Sound Laboratory for the purpose of collecting data and evaluating the various classifi- cation devices of the laboratories. It was soon-realized that the returns of a.30 day cruise viere meager as far as sample size was concerned and that a much more extenive effort involving the- operating forces as data collectors was required.- Although cooperation of the Fleet Commanders -was given,. the conditions of non-interference with.operations. made the task nigh-impossible and the laboratories retuined again to their own ships and tape recordings. Also at this time, the various labora- tories changed their emphasis toward the then rnore urgent long range detection problem. Today we find Only a moderate but balanced effort directed toward a problem which once again is 127 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 ? CIA-RDP81-01043R002200220009-0 Hiller CONFIDENTIAL coming to the front. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 A logical approach to classification by sonar is to examine what information the acoustic information can reve al about an underwater contact. The tabulation below lists the acoustic parameter and the information it contains. Acoustic Parameter Information _1. Amplitude 2. Frequency a. Size of object b. Str tictur al highlights c. Double echo effect a. Motion of object by doppler b. Motion of medium in vicinity of object by doppler Phase a. Location of object in sound beam b. Shape' and size' of object c. Heading of object d. Reflection highlights ? e. Double echo effect Thus We see that the sonar echo can reveal the size, shape, motion and unusual echo effects of underwater Objects. A 'road survey by .11RL, of researchers in various fields, verified 'this conclusion and resulted in the recommendatiOn that an ex- tensive effort be devoted to techniques and devices for analyzing the sonar echo. This was.done and each government laboratory or contractor contributed one or?more devices for this purpose. The NEL High Power Short Pulse sonar, the MIT -.ACIM, and the NRL Echotrap and SSI are a few examples. _ . ? Figures 1 through 4 illustrates the informatiOn that some of these devices a.re capable of displaying. It is shown that the sonar echo ,can be. used to show the shape, size and m9tion of underwater objects and present such positive cue's as highlights, wake effect and near beam double echo. Unfortunately, however, CONFIDENTIAL 128 ssf??? Hiller CONFIDENTIAL the illustrations show only -what -happens. with good echoes at -rela- tively.short range. ?Consider now several classification teChniques that-do -not rely on sonar. One clever method used.by the Japanese during World War II was to dump overboard a load of gravel and listen-to' the rattle on the submarine hull. MAD (Magnetic Anomaly Detector) is being continually improved and UEP (Underwater 'Electric Po- tential) research is progressing. Many ideas-have been suggested and some:have been put in practice. An example is-theNavy -Under- water Sound Laboratory's homing -drone which -seeks out-the sub- marine and magnetically attaches 'itself to the hull. Another tech- nique is the use of an MAD in a launched or dropped device, which, if placed close enough to the submarine, will send out a modulated tone received by the sonar. The -problem of getting close may have a solution in a developmental attack system called LORELI now being developed by-the Naval Research Laboratory. ? "Training-may be used to?improve classification-potential. This has been demonstrated by the 'Navy 'Electronics -Laboratory and its contractor Human TactorsResearch. Using a selected group :of submarine and non-submarine recordings, training methods have resulted in producing a-high-efficiency in classification. The various classification aids and.black boxes _Should be-thoroughly evaluated and their relation to training considered. An example is the Echotrap, figure 5, which proved-to be of little value to -the operator for the conditions under whichtested. 'The short range ,df th.e.-echoes precluded the trapping :of ,an'"average echo" and-the limitations of-the rec9rder prevented accurate doppler mea-suremeit. However, -the-echotra-p -philosophy is being -revived for long range sonars where the dead time between echoes'is la-rge. Also, ne:w digital recorders under development'-would be compatible with the measurement of doppler at the low frequencies of-the long-range sonars. The rather narrow objective of-the -black 'box.for classification caused NR-L -to take abroad look-at-the -prciblero: was decided that perhaps an approach would be to take advantage of all available experience -and devise -a.sirriple computer which would consider all factors involved. This was the'Classification Guide Rule illustrated in figure 6. It is a probabalistic-additive CONFIDENTIAL 129 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Hiller CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 computer, havirg a, weighted yes-no undetermined output:' It was ? sent to various training commands for comment and suggestionls as to the weighing factors to be used. In general, the quite varied but suggested application as a training off list rather than something to be used during the process. comments were aid. and check- classification The idea, of the coMputer persisted and NRL, with the cooperation of NEL, worked out the arrangements for a logical computer using a subtractive process and based on NWIP 24-.1 the Fle_et Classification Manual. The reasoning behind the computer is shown in. figures 7 and 8. Thus the training (storage) and decision making (logical computation) have been transferred from .man to machine. .,The computer is illustrated in figure 9. 100 of the computers were sent to Atlantic and Pacific fleet destroyers and destroyer escorts for evaluation' and others_ were sent to Operational Development Force and several labora- tories for comment, The results were varied but several general conclusions can be made. The fleet saw little value in it for solving the classification problem but did consider it as a valuable training aid. An evaluation by a contract laboratory implied the computer idea valid but suggested that the probabalistic - additive mode of operation should be used. The classification potential of existing sonars such as the SQS-.4 may be improved by the so-called integrated detection - classification station. The use of pre-formed beams and integratirg multiple styli recorders with echo analyzing displays, such as the gated. A-.scan and tactical range recorder are under current develop- ment-by NEL and NRL, figure 10. _In,summary it has been shown that there are ?devices that can classify at short ranges under good sound conditions. We also know that training can improve proficiency in classification and that the fundamental concept of the computer is sound. It therefore seems that the, future course to take is: 1. Implement an extensive data collection program in- volving the operating forces., 130 CONFIDENTIAL Hiller CONFIDENTIAL 2. Develop training devices so that operators can get more "on target" time with the sonar. 3. Install in quantity, in fleet ships, those devices that show classification potential (SSI, gated range recorder). 4. Develop a new classification computer based on the experience gained and send out to the fleet for evaluation. 5. Review the existing classification manuals to include up-to-date and correct information. 6. And finally consider the integration of classification devices with new and developmental systems that are capable of localizing the target within effective range of these devices. 131 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Confidential Hiller SUBMARINE - SHOWING POSITION IN SOUND BEAM AND LENGTH SUBMARINE -RECEIVER ADJUSTED TO SHOW HIGHLIGHTS ? SHORT RANGE SECTOR SCAN RECEIVERS DISPLAYS Figure 1 CONFIDENTIAL NEAR BEAM Hiller SURFACE ECHO TARGET BEAM SSI SURFACE ECHO PRESENTATIONS ???? I SUBMARINE AND TRANSPONDER - SHOWING RELATIVE POSITION OF SUBMARINE AND ATTACKER PULSE LENGTH' RANGE: *. QUARTER QUARTER? STERN NEAR BEAM- WITH SURFACE ECHO 132 S S I ASPECT PRESENTATIONS Figure 2 CONFIDENTIAL ? 3-5 MILLISECONDS 500 YARDS Figure 3 Figure 4 133 ECHOTRAP PRESENTATION Frequency Arniplitude CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Hiller CONFIDENTIAL CONFIDENTIAL CLASSIFICATION BY TRAINING AND INTERPRETATION NRL ECHOTRAP Figure 5 I I ? ttC _at swim dab lat.1!4 bet?? own i???t?I;e. zatiLETA7E0 Figure 7 CLASSIFICATION. BY MEASUREMENT AND LOGICAL COMPUTATION SOOLI T11211Cii IIISIIEMENI nouns Shut, .14 -? ..... .f.,'.714/11113 basic %MI teu Figure 6 t t -.1A:amor "MAH" THE MEASURER MEASURING' -DEVICE ,I ? ISOU Iii U Untie( -? ALL TANNING NOISE AND EXPERIENCE IN NAVY STORAGE AND ' LOGICAL - COMPUTATIOD' , RADAR ECM LOOKOUTS ETC Figure 8 CONFIDENTIAL CONFIDENTIAL- Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 CONFIDENTIAL Hiller .'0UALITY, ?STONGTH - ' MU NY 6 RIP ST MED DEPTH-RECORDER ? , NEE 11EG. &EN) SUI-11014 ON fl SUN?MI/ATER '.47.1. SUI-VNECT SUL SHIP?IHNECT NIV SHIP?SOW SNIP?SEAN ON e.:A? LEAD 1. Loll SHORT " 40 in dco 40 W_I 0 20 3 cc i - 7 w o 11- - 2 x w CZ W u) w c? Cr 0 a. 0 10 FREQUENCY (CPS) Figure 3 I . . WATER DEPTH (FATHOMS) - ? = 10-24 ? = 25-49 ? = 50-100 ? . ? ? z OVER 100 ? ? ? ? ?r Ai A ? ? ? _A s Ite ? 1 ? ? ? ? .. I ? ???- .. . r S. .? ? e . 4 ? ) ' CORRELATION COEFF IC IENT =0.757 ) _ _ ._ .?? a, ?? /1 AO 01 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 WIND VELOCITY (KNOTS) Figure 4 101 00 SECRET SECRET SLOPE (DB / OCTAVE ) -10 -9 -8 -7 6 -4 -3 -2 ? - - Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Frosch ? ? ? ? ? ? ? ? ? 0 ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? isoo CPS 15 20 IMMEDIATE WIND SPEED (KNOTS) Figure 5 25 WATER DEPTH (FATHOMS) ? = 10-24 _ ? 25-49 ? 2 50-10O --- ? = OVER 100 ? 5 . ? II ? ? ? ? 0 ? ??L ? ? ? ? NI ??? ? ? ? ? t.? ? ? ? ? ? ? ?? ? I' ? .. ? ? OW* ? MO 411111 MN OHM ? CORRELATION COEFFICIENT =-0.805 , 4 6 8 10 20 30 40 WIND VELOCITY (KNOTS) Figure 6 102 100 SECRET [ 7;5,4 SECRET SOUND PRESSURE AVERAGE (20-100 CPS) ( DB 80 70 60 50 40 30 Frosch . . . . . . WATER DEPTH (FATHOMS) - ? ? ? =10 -29 ? =30 - 00 ? =OVER 100 ? ! I * . .i. ? . a i I 1 4. ? li. ? ? ??Wino s . ? ? ? ? ?A ? ? Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 4 6810 20 30 40 WIND VELOCITY (KNOTS) Figure 7 103 1. IlICIMAN V 100 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SECRET Frosch 1 -10 0-20 -10 0-20 -10 0-20 -10 -20 -10 -20 -10 -20 -30 -20 -10-30 -20 144 C/S 258 C/S 5.10 C/S 10A C/S 19.2 C/S 33.4C/S 93.0 C/S 160 C/S 1 295 C/S , PPROXIMATE SOUND CHANNEL AXIS _.4_414_4000+1;i1_i .,--* 0 0 J.33.11 NI HI-d30 Q4 0 0 0 0 Yr 1=1 SECRET Frosch SECRET 35 30 25 20 15 ? 10 5? so 20 .10 1 1 I 1 1 1 1 I 1 1 1 1 1 OBSERVED MEAN SQUARE SOUND PRESSURE PER CYCLE BAND WIDTH AT 100 CPS MEASUREMENTS MADE WITH DEEP MOVING COIL HYDROPHONE AT SAN JUAN PR FROM 11/13/53 ? 11/27/53 MEAN LEVEL ? 24 DB VARIANCE ? * 5 3 DB -8 -10 z.12. -r4 -16 -II 20 26 -28 30 32 -14 36 -38 ?4c - 4- Figure 9 OBSERVED DISTRIBUTION OF AMBIENT NOISE LEVELS AT 100 CPS USING BOTTOMED HYDROPHONE IN 750 FEET OF WATER LAKE PEND OREILLE IDAHO iiiiiii I I I -3/ -33 -AK -SS -SS -37 -31 -IS -40 -41 -42 -43 -44 -45 -41 -4? -44 -48 08 LEVEL Figure 10 105 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SECRET Frosch AMP AMP RECORDING SYSTEM Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: CIA-RDP81-01043R002200220009-0 FILTER CLIPPER -1--, FILTER - CLIPPER MULTIPLIER Fig. 11 - System to Measure Expectation Value of COS (2P SECRET Frosch SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: CIA-RDP81-01043R002200220009-0 Frosch VERTICAL NOISE CORRELATION phj AS A FUNCTION OF DELAY Ger FOR AMBIENT NOISE FREQUENCY BAND 74-108 CYCLES T1ME:0325 8-13-56 CORRELATION CURVE FOR OFNCOECTIONAL NOISE SECRET Frosch CORRELATiONAVE FOR A # DISTRIBUTION LEAST SQUARES FIT TO EXPERIMENTAL DATA USING Als)?.0407?2912 ??? I ? 7017 TuTTE CORRELATION CURVE FOR A mxT I DiSTRIBUTION SCHEMATIC REPRESENTATION OF ARRAY MOUNTING ..Eigur.e 13 MARKER LAXWATORY BUOY SHIP SUBSURFACE FLOAT PLOUGH STEEL CABLE LONG LIGHT SIGNAL WIRE TYPE WCII/TT .sAY ELEMENTS RECEIVING ELEMENTS ADDER CIRCUITS AND FREQUENCY M:OULATCRS Figure 15 ANGULAR DISTRIBUTION OF AMBIENT NOISE AS DETERMINED BY CORRELATION METHOD TIME:0325 8-13-56 40. 20'N 72.18'W BOTTOM Figure 14 SE.CRET SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 ? CIA-RDP81-01043R002200220009 0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Frosch SECRET ANGULAR DISTRIBU TION OF AMBIENT NOISE MEASURED FROM SOUND CHANNEL AXIS 5 MAY 1955 17? 5 N 6442.8 W 2165 FATHOMS 106 - 150 CYCLES Figure 16 SECRET Frosch SECRET SCHEMATIC REPRESENTATION OF CONES OF RECEPTION OF VERTICAL ARRAY POSITIONED AT AXIS OF SOUND CHANNEL SURFACg .?,3600 FT -.12000 FT OR MORE CRITICAL RAY SURFACE RECEIVING ARRAY CRITICAL. RAY BOTTOM _ //2?T7//////////// EXTREME GRAZING RAY Figure 17 111 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 ? CIA-RDP81-01043R002200220009 0 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SOUND PROPAGATION MEASUREMENTS J. B. Hersey Woods Hole Oceanographic Institution 'Woods Hole, Massachusetts INTRODUCTION Several contributors to naval science early recognized the value of high explosive economical and versatile instruments for underwater acoustics research. Many of these scientists were influenced in their choice by their previous experience in commercial seismography where explosives were well established as a routine tool in seismic prospecting for oil and in related geophysical research by the mid 1920's. Furthermore the thread of awareness of the potential of explosives as sound sources has gone very pearly full circle, since a number Of the early commercial prospectors had gained their own early experience in seismography while devising systems for locating heavy enemy artillery by detecting seismic waves in the ground and sound waves in the air from the big guns of World War I. Previous to these comparatively modern uses, explosions, usually gunpowder, have been employed off and on for well over a hundred years as sound sources both in air and under water. Thus several European scientists of the 17th century timed the passage of sound over a known distance from a gunpowder shot to measure the speed of sound in air, while Maury in 1854 fired gunpowder under water in an unsuccessful attempt to measure water depth by echo sounding. There are several other similar records prior to World War I. So far as I am aware, the first extensive use of explosives under water for science or engineering was the program of radio-acoustic ranging carried out by engineers of SECRET 112 I. Declassified in Part - Sanitized Copy Approved for Release 2013/08/02: Hersey SECRET the U. S. Coast and Geodetic Survey during the 20's and 301s. They measured the travel time of acoustic waves from a dynamite shot at an echo-sounding survey ship to an anchored radio-sonobuoy and back by radio waves to the ship as a means of measuring distance to the buoy for precise navigation. The research attending their development led them to an appreciation of many of the effects subsequently studied extensively in naval underwater sound research (cf. Dyk and Swainson, 1953). Few people recognize the fact that this high precision navigational aid was used by many survey ships for several years. Since 1937 Prof. Maurice Ewing and his co-workers have carried out extensive research with explosives at sea which led directly to SOFAR and made relatively easy the discoveries of acoustic peaking in the ocean and general appreciation of the possibilities of long range sound propagation at low frequencies. Similar research has led them and several other research groups to extensive findings about the structure of the earth's crust beneath the oceans, and within the continents as well. Likewise the work by the California Division of War Research under the leadership of Dr. Eckart employed explosives extensively in their studies of underwater sound propagation, as described in Volume 7 of the NDRC Summary Volumes, "The Principles of Underwater Sound". The story of the past is all very well, and is exciting and inspiring to many of us in the present. However, explosives have remained a most durable instrument in naval science to the present day and show no indication of falling into disuse. I believe the reasons for this circumstance are significant and important to the research of the foreseeable future. Explosives were relied on initially because the chemical reaction of a high order detonation releases so large an amount of energy in so short a time. Hence high peak power. A further advantage is the broad spectrum of an explosion. The shock wave of an explosion under water contains adequate energy for a wide range of acoustical problems for frequencies between a few cycles per second and, say, 100 kc/s. A third advantage is that the initial shock is very short, and for the higher frequencies is the only considerable radiated energy. At frequencies below a few kc/s subsequent oscillations of the gas globe send out pulses which can be either confusing (if you confuse easily) or can be a distinct advantage in some research. For example, the time interval between the peaks of the shock wave and the first bubble pulse is an excellent measure of the depth of detonation for a given weight and 113 SERCET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Hersey SECRET type of explosive. The short, intense shock wave provides very high resolving power which has proven very useful in determining the exact trans- mission paths that are effective in both passive and active detection systems. As many of you know explosives have been used extensively in assessing passive detection paths in various parts of the ocean by a very simple technique of correlating pulse arrivals at short range where interpretation is unambiguous to longer ranges where identification of paths would otherwise be uncertain at best. Fig. 1 is an example of such a correlogram. It consists of a series of recordings of arrivals from a shallow shot to a shallow hydrophone at gradually increasing range. The records near the top are taken at so short a range that the paths may be certainly identified as associated with a direct transmission, single, double, triple, etc. reflections from the bottom or refractions in the outer part of the SOFAR channel. As the range increases the direct transmission path commonly deteriorates and consequently the first arrival weakens and disappears. At still longer range the first bottom reflec- tion similarly disappears, and the second, third, and so on. From the manner and range of these disappearances in different parts of the spectrum we have been able to verify many theoretical predictions about acoustical transmissions, and we have been led to the discovery and understanding of new and important effects which, while not unsuspected in most instances, nevertheless were not properly appreciated at the outset. Another example which illustrates the powerful resolution of explosion technique was a study of sound transmitted from deep water to the sloping side of an oceanic island. Here reception at a bottomed hydrophone had been observed to be approximately one-fourth as effective for steady state transmissions from one azimuth as another. By a simple extension of the correlation technique just described it was possible to show that in the "poor" direction a submerged hill acted as a screen to cut out exactly three-fourths of the total available transmission paths, whereas in the "good" direction there was no such difficulty. - Examples of this sort are legion, both in naval science and basic research in submarine seismography (cf. Hersey and Officer, 1952; Officer, 1955; Rinehart, 1955; and Anderson et al:, 1957). The broad spectrum of the shock wave gives a peculiar advantage for certain aspects of acoustical transmission studies. It is commonplace to students of sound transmission to observe very large short term fluctuations in received pressure levels 114 SECRET SECRET Hersey from continuous sinusoidal sources which result from interference between wave trains following different paths. This sort of fluctuation is virtually eliminated when levels from an explosion in the frequency band of interest are measured through a moderately broad band-pass filter. Thus explosives are time-saving as a statistical tool. This effect was demonstrated constantly during an extended sound transmission study where a single frequency source was towed from the same ship that dropped explosives. The shot results proved to represent an excellent smoothing of the continuous transmission data. Such questions as the accuracy of our knowledge of the energy. radiated by explosions and its reproducibility have often been raised. The question has been studied intensively by a number of groups interested in underwater explosions for ordnance purposes. They regard properly engineered explosives as being very reproducible indeed and our own experience with them at Woods Hole certainly indicates the same. Ordnance investigators have carefully investigated the scaling laws, have measured peak pressures and the shapes of pressure-time curves; further they have shown that the.radiation from simple spherical charges or rectangular blocks which are short compared with the wave length can be predicted with quite adequate accuracy for acoustical research from a knowledge of a few straightforward characteristics of the individual explosive. The only qualification to this statement is with respect to small charges, say of the order of half a pound or less of certain explosives, notably TNT and C3. Thus spherical charges or rectangular blocks such as the various standard demolition blocks heavier than 0.5 lb. are acoustical instruments of known accuracy when properly employed. Directional effects of explosives at range comparable to the dimensions of the charge are striking and moderately well known, and in addition the ordnance scientists know much about, tricks of producing special pressure-time variations with shaped charges. However, the directionality of explosives at several thousand yards is just beginning to be appreciated and studied intensively. We have used a simplified theory of radiation from arrays of sources to predict the directionality of linear arrays of charges, and have demonstrated qualitative agreement in practical tests at sea. While it is too early to tell how useful such devices can be, nevertheless it is certainly practical to concentrate energy of an appreciable part of the spectrum in preferred directions for long range proPagation, echo ranging, and reverberation studies. 115 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SECRET Hersey Observational Techniques As explosives have been used for more and more different purposes a rather special set of observational and analysis techniques have been developed. The interpretation of any analysis of shot data must take suitable account of the character- istics of the hydrophone, the filters and the recording system employed. When this has been done, meaningful results can be obtained. Examples of such analyses are discussed in detail by Johnson, Bradshaw and Hersey (1957) for a directional charge investigation and by Machlup and Hersey (1955) for special studies of the deep scattering layers of the open ocean. .The earliest recording of energy transmitted over long distances was on an photographic oscillogram or some sort of direct writing recorder. Recordings were compared with accurate timing so that apparent travel times or differences in travel time between recognizable events could be read. As we started to employ explosives for measuring the amplitudes of wave trains over different paths we first relied on measurements of peak amplitude. The folly of this procedure has long been recrized. Subsequently experiments with an analog computation of p2dt over the desired pulse or pulse train gave consistent results and has been widely used for the past four or five years. Results from such analyses of magnetic tape-recorded signals have been shown to compare favorably with comparable measurements from pressure-time curves of shock waves at short range recorded by ordnance scientists by.means of high speed photographing of oscilloscope traces (Weston, 1957; Hersey, 1957). In Fig. 2 are shown such comparisons from work of Weston at the Admiralty Research Laboratory and independent studies in this country. When very short pulse arrivals are being studied the more complex analog computations can be substituted by.calibrated recordings with a rectifier' feeding a galvanometer, the response of which is slow compared with the pulse length. This method must be used with due Caution as it is reliable only when this condition is 'satisfied. A number of interesting investigations of transmission and Scattering phenomena have been made by playing 'tape recordings of explosions to a sound spectrograph such as the Kay Electric Vibralyzer. Thus, as in Fig. 3, the upper limbs of the group velocity dispersion curves of the normal- modes r 116 SECRET 11 1.???? Hersey SECRET familiar to students of 'shallow water transmission are beautifully displayed by a recording of a shot arrival to this instrument. One of the important future problems of sound transmission is the accuracy of sonar data, which, in turn, requires that we know the long and short term stability of transmission paths. One proposal for such a study is to establish a suitable source and receiver well separated from one another, and transmit pulses from one to the other on a regular schedule for a year or more. Explosives would make an ideal sound source for this work except for the mechanical difficulty of placing successive charges reliably in the same place by a simple, economical method. The difficulty of identical repetition of explosive tests which this points up is perhaps the greatest shortcoming they have for work in open water. For such purposes we are seeking means of generating accurately timed, very intense short pulses. In this search various groups have tried spark sources, mechanical impulse sources, guns shot under water, and other schemes. All prove useful to a degree, but all so far have fallen orders of magnitude short of what is already available in the energy of a small block of TNT. 117 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SECRET Hersey Literature Cited Anderson, E. R., E. L. Hamilton and R. M. Lesser, 1957, Oceanographic and geologic factors influencing low-frequency acoustic transmission off northeast Oahu, Hawaii. USNEL Rept. 763, 76 pp. Confidential. Dyk, K. and O. W. Swainson, 1953, The velocity and ray paths of sound waves in deep sea water. Geophysics, vol. 18, pp. 75-103. Hersey; J. B., 1957, Comments on D. E. Weston's "Underwater explosions as acoustic sources". Jour. Underwater Acoust., vol. 7, pp. 135-137. Confidential. Hersey, J. B. and C. B. Officer, 1952, Transmission tests at USNEF, Eleuthera, July-August 1952. WHOI Ref. No. 52-100, 20 pp. Secret. Johnson, H. R., 1955, A 320 mile sound transmission run SE from Bermuda. WHOI Ref. No. 55-27, 5 pp. Confidential. Johnson, H. R., A. Bradshaw and J. B. Hersey, 1957, Three types of directional explosive sound sources. WHOI Ref. No. 57-21, 25 pp. Confidential. Machlup, S. and J. B. Hersey, 1955, Analysis of sound-scattering observations from non-uniform distributions of scatterers in the ocean. Deep-Sea Res., vol. 3, pp. 1-22. - Milne, Allen and J. B. Hersey, 1958, Sound Transmission to the Cove Point Geophone at the U. S. Navy Bermuda Sofar Station. WHOI Ref. No. 58-5, 29 pp. Confidential. Officer, C. B., 1955, A deep-sea seismic reflection profile. Geophysics, vol. 20, pp. 270-282. Officer, C. B., L. C. Davis, and J. B. Hersey, Transmission tests at USNEF, ELEUTHERA 29 July to 1 August 1952, Part III. WHOI Ref. No. 54-49, 10 pp. Secret. Rinehart, M. C., 1955, Low frequency sound propagation studies. Project MICHAEL, Tech. Rept. No.. 38, 109 pp. Confidential. Weston, D. E., 1957, Underwater explosions as acoustic sources. Jour. Underwater Acoust., vol. 7, pp. 107-134. Confidential. ,5;7=4..,Ams=1".:Isceramsa. 118 SECRET 3 SECRET Hersey Fig. I - Correlogram of Shot Arrivals for a 330-Mile Trans- mission Run SE of Bermuda 119 "5 '75. 71 11- 1 41 9840 118 14- 137.2 141 SI 144.42 141.2 4104 201.2 20545 211.34 1111.5 1/1.59 251.70- 2411.82 211119 313.9)? ? "" 315,60 333 01-12?=-Lj4"..42.7... 341 I 4 551 72 ! 375 41414 2 421, 25- 4 )4.95 ? ? ? ??? , ? - ; 454.71? I 492.53 497.45 507.30- 1521.51- 555.5,- 515,29 540.24 1141.2,- 449 58 ' MA N$( IN K/LOYANDS cc) 67 % % I0 en 812 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SECRET .0 20 10 0 ?10 20 Hersey' ENERGY SPECTRUM LEVEL 9 QUEEN} X NAN W.H.0.1.54-49 lil JOHNSON. 1955 IN DS RE i UPPER EXTREM MEDIAN MEDEA LOWER EXTREME ? I .?.? ERS/CM2/C/S AT FOR OF 100 TNT YDS. I LS. ? SOURCEt I 1 M 2 DEMOLITION BOMB ElX o El ... FREOUEN Y. KILOCYCLES _____1 PER SECOND I L 0.01 0.1 10 Fig. 2 - Shot Spectrum Inferred from Long-Range Transmission Compared With Short-Range Meas- urements. N... Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 SECRET 120 4 SECRET '04000 c.) N.3000 ,42 2000 1000 0-- (..)4000 Q. 2.3000 33 10 2000 .000 12 5 KYDS. 0 67 KYDS. 9 5 KYDS. 2 4 KYDS. Hersey CLOSING RANGE 4000 ? 3000 ^ .2000 1000 5.(:KYDS. 3 2 KYDS. 2 4 KYDS 1 47 kYOS. OPENING RANGE 4000 3000 ? 2000 ? 1000 5 2 KYDS 7 6 KYDS 0 02 04 06 -1111111111111 r/ME IN SECONDS 9 3 KYDS. 24 KYDS Zig. 3 - Sound Spectograms of Shallow Water Shot Arrivals 121 SECRET Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0 Declassified in Part - Sanitized Copy Approved for Release 2013/08/02.: CIA-RDP81-01043R002200220009-0 A t? Waal, UNCLASSIFIED Office of Naval Research. ONR-3 Supplement(SECRET] A Symposium 7 THE OCEAN AS THE QPERATING ENVIRONMENT OF THE NAVY "Unclassified Titlej? 121 pp. and figs., March 1958. The Office of Naval Research, in sponsoring annual symposia on basic and applied science in the Navy, has in March 1958 covered the subject of the oceans ind many topics related to the seas. Twenty?five papers were presented on topics of navy?wide interest such as hydrobiology, buoys, Arctic oceanography, under? water acoustics, radioactivity in the seas, marine propulsion-devices, hydrodynamics, and underwater ordnance. Presented in this volume are seven techni? cal papers covering the secret presentations. UNCLASSIFIED 1. 2. 3. Oceanography Underwater sound Marine biology 4. Underwater ordnance 5. Hydrodynamics UNCLASSIFIED Office of Naval Research. ONR-3 Supplement[SECRET] A Symposium 7 THE OCEAN AS THE QPERATING ENVIRONMENT OF THE NAVY "Unclassified Titlej. 121 pp. and figs., March 1958. The Office of Naval Research, in sponsoring annual symposia on basic and applied science in the Navy, has In March 1958 covered the subject of the oceans and many topics related to the seas. Twenty?five papers were presented on topics of navy?wide interest such as hydrobiblogy, buoys, Arctic oceanography, under? water acoustics, radioactivity in the seas, marine propulsion devices, hydrodynamics, and underwater tordnanci. Presented in this volume are seven techni? cal papers covering the secret presentations. UNtLASS1FIED . Oceanography . Underwater sound 3. Marine biology 4. ? Underwater ordnance . Hydrodynamics UNCLASSIFIED , Office of Naval Research. ONR-3 Supplement[SECRET] A Symposium 7 THE OCEAN AS THE QPERATING ENVIRONMENT .OF THE NAVY "Unclassified Titlej. 121 pp. and figs., AMarch 1938. The Office of Naval Researchl in sponsoring annual symposia on basic and applied science in the Navy, has :in March 1958 covered the subjectof the oceans and tmany topics related to the seas. Twenty?fivo papers were presented on topics of navy?wide interast such as hydrobiology, buoys, Arctic oceanography, under? 'water acoustics, radioactivity in the seas, marine ,propulsion devices, hydrodynamics, and underwater ordnance. Presented in this volume are seven techni? cal papers covering the secret presentations. UNCLASSIFIED 1. Oceanography 2. Underwater sound 3. Marine biology 4. Underwater ordnance 5. Hydrodynamics UNCLASSIFIED Office of Naval Research. ONR-3 Supplement[SECRET] 'A Symposium 7 THE OCEAN AS THE QPERATING ENVIRONMENT OF THE NAVY 'Unclassified Titlej. 121 pp. and figs., March 1958. The Office of Naval Research, in sponsoring annual symposia in basic and applied science in the Navy, has in March 1958 covered the subject of ihe oceans and tmany topics related to the seas. Twenty?five papers were presented on topics of navy?wide Interest such as hydrobiology, buoys, Arctic oceanography, under? water acoustics, radioactivity in the seas, marine' propulsion devices, hydrodynamics, and underwater ordnance. Presented in this volume are seven techni? cal papers covering the secret presentations. UNCLASSIFIED 1. Oceanography 2. Underwater sound 3. Marine biology 4. Underwater ordnance 5. Hydrodynamics Declassified in Part - Sanitized Copy Approved for Release 2013/08/02 : CIA-RDP81-01043R002200220009-0