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Department of the Air Force and the Navy. AFM 51-40. Air Navigation. Flying Training PDF

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Preview Department of the Air Force and the Navy. AFM 51-40. Air Navigation. Flying Training

DOCUMENT RESUME ED 082 051 CE 000 350 TITLE Air Navigation. Flying Training. AFM 51-40. NAVAIR 00-80V-49. INSTITUTION Air Training Command, Randolph AFB, Tex- SPONS AGENCY Department of the Air Force, Washington, D.C.; Department of the Navy, Washington, D.C. REPORT NO NAVAIR-00-80V-49 PUB DATE 1 Jul 73 NOTE 452p. AVAILABLE FROM Superintendent of Documents, U.S. Government Printing Office, Washington, D.C. 20402 ($4.50) MF-$0.65 HC-$16.45 EDRS PRICE. DESCRIPTORS Astronomy; Aviation.Technology; *Equipment; *Flight. Training; Instrumentation; Job Training; *Manuals; Military Personnel; *Navigation; *Techniques IDENTIFIERS *Air Navigation ABSTRACT This manual provides information on all phases of air navigation for navigators and student navigators in training. It develops the art of navigation from the simplest concepts to the most advanced procedures and, techniques. The text contains explanations on 'how to measure, map, and chart the earth; how to use basic instruments to obtain measurements of direction, altitude, temperature, and speed; and how to solve basic navigation problems by dead reckoning and map reading. Special techniques used to navigate by radio, radar, and Loran; by using celestial concepts and procedures; and in polar areas are covered. There is information on flight publications, weather services, mission planning, inflight procedures, and low level navigation. The final chapters cover automatic navigation systems and aerial delivery. (Extensive diagrams, illustrations and photographs are included together with attachments on symbol definitidns and term explanations.) (Author/KP) FILMED FROM BEST AVAILABLE COPY Lc' OF HEALTH. U S DEPARTMENT EDUCATION & WELFARE OF NATIONAL INSTITUTE FOUCATION REPRO HAS BEEN F Pam THIS DOCUMENT AS PECEIvE0 DUCE() EXACTLY OPC.AN,IATION OP,G/N OP)NIONS THE PE PSON OP OT v[EV. OP A'INC, $1 POINTS PEPPE NECESSAR,L Y STATED 00 NOT INST MITE Of F ICIAt OP POLICY SENT EDUCATION POSITION DEPARTMENTS OF THE AIR FORCE AF MANUAL 51-40 AND THE NAVY NAVAIR 00-80V-49 Washington DC 20330 1 July 1973 Flying Training AIR NAVIGATION . . This manual provides information on all phases of air *navigation for navigators and student navigators in training. It develops the an of navigation front the simplest concepts to the most advanced proce- dures and techniques. The text contains explanations on how to measure, map, and chart the earth; how to use basic instruments to obtain measurements of direction, altitude, temperature, and speed; and how to solve basic navigation problems by deed reckoning and map reading. Special techniques use..",, navigate by radio, radar, and Loran; by using celestial concepts and procedures; and in polar areas are covered. There is information on flight publications, weather services, mission planning, in- flight procedures, and low level navigation. The final chanters cover automatic navigation systems and aerial delivery. CONTENTS Chapter Page Introduction 1-1 I Earth and Its Coordinates 2-1. 2 Maps and Charts 3-1 3 Basic Instruments 4 4-1 Dead Reckoning 5-1 5 Lines of Position, Bearings, and Fixes J. -6 6-1 ......... Map Reading i 7 7-1 I Practical Application of DR and Map Reading 8-1 8 Radio 9 9-1 Radar 10-1 10 '' Celestial Concepts. 11-1 11 Time 12 12-1 Computing Altitude and True Azimuth 13 13-1 Plotting and Interpreting Celestial LOPs 14 14-1 Sextants and Errors of. Observation 15 15-1 Special Celestial Techniques 16 16-1 Celestial Precomputation 17 17-1 Star Identification 18 18-1 I Aug 68, as amended; AFM 51-40, Vol iII, May 59; NAVAIR 00-80V-49, 15 Oct 59, as Supersedes AFM 51-40, Vol I, amended; and NAVAIR 00-80V-5I, May 59, as amended. (For summary of revised, deleted or added material, see signature page.) OPR: AFDPPTF (Prepared by Hq ATC/DON) DISTRIBUTION: F Air Force: Navy: Published by Air Trashing Command in accordance with AFM 5-1, Chapter 13. For sale by the Superintendent of Documents, U.S. Government Printing Office, Washington, D.C. 20402 Bookstore Price: $4.95, domestic postpafcb $4.50, GPO Chapter.. Page GriciNavigation 19 19-1 20 Pressure Differential Techniques. 20-1 Loran 21 21-1 22 Flight Information Publications and Air Traffic Control 22-1 Weather Station Services 23 23-1 24 Mission Planning 24-1 Inflight Procedures.. 25 Low Level Navigation 26 25 -1 : Automatic Navigation Systems 27 27-1 Aerial Delivery 28 28-1 A ttaclunent Symbols: A1-1 1 . Abbreviations 2 A2-1 Explanation of Terms A3-1 3 Index A4-1 4 - CHAPTER 1 Introduction Some form of navigation has been used ever DEFINING AIR NAVIGATION since man has ventured from his immediate sur- The word navigator comes froth two Latin roundings with a definite destination in mind. words, navis, meaning ship, and agere, meaning Exactly how the earliest navigators found their to direct or move. Navigation is defined as the matter of con- way must remain to some extent a ocess of directing the movement of a craft from jecture but some of their methods are known. For one pia= to another. The craft may be in example, the Phoenicians and Greeks were the its broadest sense any object requiring direction or first td navigate far from land and to sail at night. Unlike sea or naval capable of being directed. They made primitive charts and used a crude form . air navigation movement navigation, involves of dead reckoning. They used observations of the above the surface. of the earth within or beyor.d sun and the North Star, or pole star, to determine the atmosphere. Air navigation, then, can be de- direction. Early explorers were aided by the in- fined as "the process of determining the geographi- vention if the astrolabe (see figure 1-1), but it was cal position and of maintaining the desired direc- not until the 1700's that an accurate chronometer tion of an aircraft relative to the surface of the (timepiece) and the sextant were invented making Other terms, "avigation" and "aerial earth." it possible for navigators to knoW exactly where navigation" have fallen into disuse in favor of they were, even when far from land. the term, "air navigation." Certain unique condi- Any purposefulmovement in the universe ulti- mately involves an intention to proceed to a tions are encountered in air navigation that have a special impact on the. navigator. definite point. Navigation is the business of pra Need for continued motion. A ship or land ceeding in such a manner as to arrive at that point. To do this safely is an art. Navigation is con- vehicle can stop and resolve any uncertainty of motion or await more favorable conditions sidered both an art and a science. Science is in- if necessary. Except to a limited extent, most air- volved in the development of instruments and methods of navigation as well as in the coniPuta- craft must Neu going. Limited eil. ranee. Most aircraft can remain tions involved. The skillful use of navigational in- struments and the interpretation of available data aloft' for only a relatively short time, usually a may be considered an art. This combination has matter of hours. Greater speed. Navigation of high speed air- led some to refer to navigation as a "scientific art:: craft requires detailed flight planning and naviga- tion methods and procedures that can be accom- As instruments and other navigational aidi have become_more complicated,,_ an- increasing propor- plished quickly and accurately. tion of the developnient has been shifted from the Effect of weather. Visibility affects the availa- practicing navigator to the navigational. scientist bility of, landmarks: The wind has a more direct who aids in drawing together the applications of effect upoh the position of aircraft than upon that principles from such' sciences as astronomy, cartog- of ships or land vehicles. Changes of atmospheric raphy, electronics, geodesy, mathematics, mete- pressure and temperature affect the height meas- orology, oceanography, and physics. Such applica- urement of aircraft using barometric altimeters. 1-1 Figure 1-1. The Ancient Astrolabe tions aid in explaining navigational phenomena AIR NAVIGATION PROBLEM and in developing improvements in speed, ac- The problem of air navigation is, primarily, to curacy, or routine actions in practicing the "scien- determine the direction necessary to accomplish tific art" of navigation. the intended flight, to locate positions, and to The beginning navigator largely practices the measure distance and time as means to that end. science of navigation; that is, he gathers data and When navigation is performed without "aids," uses it to solve the navigation problem in a more or that is, without obtaining or deducing position in- less mechanical manner. It is not until after many formation from special equipment specifically de- hours of flying that the navigator begins to realize signed to provide only momentary knowledge of that his total,role involves an integration based ca judgment. The navigator builds accuracy and re- position, the basic method of navigation, "dead liability into his performance by judgment based reckoning," is 'used. The military navigator is an upon experience. Dead reckoning is the determination of position indispensable part of many offensive and defeniive by advancing a previous position, using only direc- missions. He must be able to plan a mission tion and speed data. The navigator does this by covering every eventuality; inflight, he must be able applying, to the last well-determined position, a to evaluate the past and current progress of the vector or a series of consecutive vectors represent- aircraft and to derive a correct conclusion for the ing the magnitude and direction of movement that remainder of the mission. High speed navigation has been made since the previous position. The demands that he have the ability to anticipate changes in flight conditionsto think ahead of new position obtained is for a specific time and is the aircraftand to make the correct decision essentially a predicted or theoretical position. The immediately on the basis of anticipated changes. navigator assumes that he can use direction and 1-2 principles and procedures of air navigation used speed data oreviously determined with reasonable accuracy to obtain a future position. by pilots and information on the navigation sys- tems used by other crew members of multi-place The most important elements in the plotting of a dead-reckoning position are elapsed time, direc- aircraft. U. S. Air Force, Navigator Refresher Course, tion, distance, and speed. Knowing these and his a pro- AFP 60-1-1, 60-2, and 60-3. This starting point, a navigator can plot his approximate is position, which in turn, can serve as a base for a grammed text and ground mission primarily used for navigators requiring annual refresher training. subsequent course change. When the function of air navigation is per- USAF, Air Training Command, The Navigator, formed with "aids" to navigation, the navigator USAFRP 50-3, published three times per year by can provide a new and separate base or starting ATC. This magazine contains a variety of articles point from which to use dead reckoning pro- from world-wide sources that relate to navigation cedures. When an aid to navigation provides the and which advance new and different means for navigator with a position or fix,, any cumulative accomplishing techniques of navigation. errors in previous dead-reckoning dements are The following United States Observatory and . cancelled. In effect, the navigator can restart the U.S. Navy Oceanographic Office publications are mission, as far as the future is concerned, from also prescribed for Air Force use: each new fix or accurate position determined by Air Almanac the use of aids. American Ephemeris and Nautical Almanac often used with the word, An adjective H.O. Pub 9 (Part II), "Useful Tables for the is to indicate the type or primary "navigation," American Practical Navigator" H.O. Pub 211, "Dead Reckoning Altitude and method being used, such as dead reckoning naviga- tion, celestial navigation, radar navigation, pres- Azimuth Tables" sure pattern navigation, doppler navigation, grid H.O. Pub 249, "Sight Reduction Tables for Air navigation, inertial navigation, etc. Navigation" The Department of Defense (DOD) Catalog of Aeronautical Charts and Flight Publications, pub- SOURCES OF NAVIGATION INFORMATION lished 'by the Defense Mapping Agency (DMA) contains information on the basis of issue and In addition to this manual, several other sources procedures for requisitioning these publications. provide complete or partial references to all meth- The use of the Air Almanac and H.O. 249 Tables ods and techniques of navigation. Some of these is discussed in cietail later in this manual. are: U. S. Navy Oceanographic Office, Air Naviga- tion, H.O. Pub 216. Tfililrageneral reference SUMMARY book for air navigators. U. S. Navy Oceanographic Office, American Some form of navigation has been accomplished since the ancient Greeks and Phoenicians begin Practical Navigator, Bowditch, H. 0. Pub 9. An epitome of navigation, this text provides a com- sailing far from land. The problems 'of air naviga- pendium of navigational material. Although de- tion and the navigator today are far different from signed primarily for the marine navigator, it has those experienced by these ancient mariners. With the advent of newer and higher speed aircraft, the valuable application for the air navigator: navigator must be able, to quickly and, accurately United States Naval Institute, Navigation and. Piloting, Dutton. This is a teaching text for the make decisions which directly affect the safety of the aircraft and the crew. Using proven techniques elements of marine navigation. and modern aids, the navigator practices a scien- Air Training Command, Navigation for Pilots, ATCM 51-7. This manual explains the basic tific art. 1-3 CHAPTER Earth and Its Coordinates (1) the hour of the day and (2) an elapsed INTRODUCTION interval. Basic to the study of navigation is an under- The methods of expressing position, direction, standing of certain terms which could be called the "distance, and time are covered fullyin,app.opriate dimensions of navigation. These so-called dimen- chapters. It is desirable at this time to emphasize sions of position, direction, distance, and time are tht! these terms, and others similar to them, repre- basic references used by the air navigator. A'clear sent definite quantities or conditions which may __,understanding of these dimension's as they :relate be measured in several different ways. For ex- to navigation is necessary to provide.the navigatoi ample, the position of an aircraft may be expressed with a means of expressing and accomplishing the certain latitude- and in coordinates such as . at These 'terms practical aspects of air navigation. longitude. The position, may also be expressed as being 10 miles southof, a certain city. The study are defined as follows: . Position is a point defined by stated or implied of navigation demands that the navigatorlea'rn how coordinates. Though frequently qualified by such to measure quantifies such as those just defined and adjectives as "estimated," "dead reckoning," "no how to apply the units by which they are expressed. wind," and so' forth, the word "position" always It is refers to some place that can be identified. EARTH'S SIZE AND SHAPE obvious that a navigator must know his position before he can direct the aircraft to another position For most navigational purposes, the earth is assumed to be a perfect sphere, although in or in another direction. Direction is the position of one point in space Inspection of the earth's crust reality it not. is relative to another without reference to the dis- reveals that .there is a height variation of approxi- tance between them. Direction is not in itself an mately 12 miles from the top of the tallest moun- is often measured in terms of its angle, but it tain to the bottorn of the deepest point in the ocean. angular distance from a reference direction. Smaller variations in the surface (valleys, mOttit: Distance is the spatial separation between, two tains, oceans, etc.) cause an irregular appearance. points and is measured by the length of a line Measured at the equator, the earth is approxi- joining them. On a plane surface, this is a simple L'7fnately 6,887.91 nautical miles in diameter, while the polar ,diameter is approximately 6,864.57 nau- problem. However, consider distance on a sphere, tical miles. The difference in these diameters is where the separation between points may be ex- 23.34 nautical miles, and this difference may be preSsed as a variety of curves. It is essential that It is used to express the ellipticity of the earth. the navigator decide exactly "how" the distance is to be measured. The length of the line, once sometimes expressed as a ratio between the differ- the path or direction of the line has been 'deter- ence and the equatorial diameter: f.71 mined, can be expressed in various units; e.g., 22.34 1 Ellipticity = miles, yards, and so 'forth. 295 6,887.91 Since the equatorial diameter exceeds the polar Time is defined in many ways, but those defini- tions used in, navigation consist Mainly of two: diameter by only 1 part in 295, the earth is very 2.1 nearly spherical. A symmetrical body having the same dimensions as the earth, but with a smooth surface; is called an oblate spheroid. In figure 2-1, Pn, E. Ps, and W represent the surface of the earth, and Pn-Ps represents the axis of rotation. The earth rotates from W to E. All points in the hemisphere Pn, W; Ps approach the reader, while those in the opposite hemisphere re- cede from him. The circumference W-E 'is called the equator, which is defined as that imaginary the surface of the earth whiz& plane circle passes through the center of the earth and is per- pendicular to the axis of rotation. Great Circles and Small Circles A great circle is defined as a circle on the surface of a sphere whose center and. radius are those of IRCLE CSMALL the sphere itself. It is the largest circle that can be drawn on the sphere; it is the intersection with the surface of the earth of 'any plane passed through the center. GREAT RCLE The arc of a great circle is the shortest distance between two points on a sphere, just as a straight line is the shortest distance between two points on a plane. On any sphere, an infinitely large number of great circles may be drawn through any point, though only one great circle may be drawn through any two points that are not diametrically opposite. Several great circles are, shown in figure 2-2. The largest circle possible whose, center is also the center °Utile sphere is called a GREAT CIRCLE. All other circles ore small chiles. GREAT CIRCLE Figure 2-?. A Great Circle the Largest Circle Figure 2-1. the Earth Schematic Representation is of, in a Sphere Showing Axis of Rotation and Equator 2-2 ence. A system of coordinates has been developed Circles on the surface of the sphere other than great circles may he defined as small circles. A to locate positions on the earth by means of imagi- These lines are known as nary reference lines. small circle is a circle on the surface of the earth whose center and/or radius are not that of the parallels of latitude and meridians of longiv de. sphere. A special of small called' set circles, Once a day, the earth rotates on its LATITUDE. latitude, is discussed later. north-south axis which is terminated by the two poles. The equator is constructed at the midpoint In summary, the intersection of a sphere and a a circlea great circle plane the plane of th:s axis at right angles to it (see figure 2-3). A is if great circle drawn thfough the poles is called a - passes through the center of the sphere, and a meridian, and an infinite number of great circles small circle if it does not. may be constructed in this manner. Each meridian Latitude and Longitude is divided into four quadrants by .the equator and the poles. Since a circle is arbitrarily divided into The nature of a sphere is such that any point 360 degrees, each of these quadrants therefore on it is exactly like any other point. There is contains 90 degrees. neither beginning nor ending as far as differentia- Take a point on one of these meridians 30 tion of points is concerned. In order that points degrees north of the equator. Through this point may be located on the earth, some points or lines pass a plane perpendicular to the north-south axis of reference are inecessary so that other points may of rotation. This plane will be parallel to the plane be located with regard to them. Thus the location of the equator as shown in figure 2 -3 and will of New York, City with reference to Washington intersect the earth in a small circle called a parallel D. C., is stated as a number of miles in a certain or parallel of latitude. The particular parallel of direction from Washington. Any point on the latitude chosen is at 30° N, and every point on earth can be located in this manner. this parallel will be at 30°N. In the same way, Such a system, however, does not lend itself other parallels can be constructed at any desired readily to navigation, for it would be difficult to latitude, such as 10 degrees, 40 degrees, etc. locate a point precisely in mid-Pacific without any Bear in mind that the equator is drawn as the nearby known geographic features to use for refer- The plane of a Parallel is The Equator and poles divide Meridians parallel to the Equator. into four equal ports. The Equator is a great circle Great circles through the T'ane is perpendicular who poles form Meridians. to the axis. Planes of the Earth Figure 2-3. 2-3

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NAVAIR-00-80V-49. Air Training Command, Randolph AFB, 1973. - 453 p.This manual provides information on all phases of air navigation for navigators and student navigators in training. It develops the art of navigation from the simplest concepts to the most advanced procedures and techniques. The tex
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Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.