10. EARTH OBSERVATIONS AND PHOTOGRAPHY EXPERIMENT MA-136 Farouk El-Bazat and D. A. MitcheUa ABSTRACT The Gemini, Apollo, and Skylab missions showed that orbiting astronauts can provide valuable data composed of visual observations and photographs. For this reason, the primary objectives of the Earth Observations and Photography Experi? ment of the Apollo-Soyuz Test Project were to photograph various terrestrial struc? tures and to use the capabilities of man as a trained observer in visually studying Earth features and phenomena. Man I s special capabilities include the sensitivity of the eye to subtle color variations and the speed with which the eye-brain system can interpret what is seen and select targets for photography. Real-time astronaut observations constitute a useful complement to orbital photographs and greatly aid in their interpretation. Targets for mapping and hand-held photography were selected on the basis of their value to specialists in the Earth sciences including geology, oceanography, desert study, hydrology, meteorolOgy, and environmental science. INTRODUCTION Background The experiences of the Gemini, Apollo, and Skylab Programs proved that scientifically interesting features can be selected and photographed by observers in space. Photographic records of these programs include a plethora of valuable scenes taken from orbital altitudes, both from Earth orbit (e. g. , refs. 10-1 to 10-4) and from lunar orbit (e.g. , refs. 10-5 to 10-7). During the Apollo Program, it became apparent that the orbiting astronauts could see more than what was recorded on film. To test this capability , plans were made, beginning with the Apollo 13 crew, to train Moon-bound astronauts to make visual observations. However, because the Apollo 13 mission was aborted, the first attempt at making visual observations from lunar orbit was made on Apollo 14. The results were encouraging (ref. 10-8), and a program was developed for the systematic acquisition of scientifically relevant data on Apollo 15 (refs. 10-9 and 10-10), Apollo 16 (refs. 10-11 and 10-12), and Apollo 17 (refs. 10-13 and aNational Air and Space Museum, Smithsonian Institution. t Principal Investigator. 10-1 10-14). Emphasis was placed on the command module pilot (CMP) of each Apollo mission because he spent more time in lunar orbit than did his crewmates. Also, premission training and data acquisition were limited to the field of lunar geology during the Apollo missions. The Skylab Program provided the first opportunity to pursue a systematic visual study of the Earth. However, this study was done only on the last of three missions, Sky lab 4. Because of the nature of the Earth, the Skylab visual obser? vations program included geology, oceanography, hydrology, meteorology, etc. (ref. 10-15). The long duration of the mission (84 days) allowed repeated observa? tions of the same area and during different seasons. Observations on Sky lab 4 and their documentation with photographs proved to be a very worthwhile effort and resulted in significant findings (ref. 10-15). During the Apollo-Soyuz Test Project (ASTP), selected features of interest from the Skylab Earth observations program were reexamined and viewed from a different altitude, 2 years later in time. Visual Observation Team To assist in the planning and implementation of the ASTP Earth Observations and Photography Experiment, a team of experts in the fields of geology, ocean? ogr aphy, desert study, hydrology, meteorology, and environmental science was ass embled. The Earth observations team (table 10-I) was composed of 42 individ? uals, including the Principal Investigator (PI) and 12 Co-Investigators (Co-I). The responsibilities of this team of experts and support personnel were as follows. 1. To collect and compile problems to be solved in support of ongoing res earch in the Earth sciences. 2. To evaluate and select achievable goals based on experience and level of crew training. 3. To recommend and pursue a training program of mutually acceptable p rocedures and sites. 4. To identify Flight Plan requirements and tools necessary to achieve the objectives. 5. To support the mission operations for nominal and contingency flight plans. 6. To report the results and the possible applications to future space flight. Earth Observation Sites The primary objective of the ASTP Earth Observations and Photography Experiment was to use the Apollo and Skylab experiences in acquiring photographs of specific Earth fe atures, processes, and phenomena and in making visual obser? v ations from orbit to complement photographic data. Visual sightings are needed because the extensive dynamic range and color sensitivities of the eye cannot be matched by anyone film type and also because, in special cases, on-the-scene interpretations of obscured features and phenomena are necessary. 10- 2 ~ ____ J To achieve the primary obj ective, both photographic mapping and visual observation sites were included in the Flight Plan. A total of 11 mapping sites (table 10-II) and 12 visual observation sites (fig. 10-1) were selected. The 12 visual observation sites were chosen according to geographic localities and included 60 specific targets of prime scientific interest (table 10-III). This method of target identification made it possible for both planners and astronauts to easily discuss and locate targets selected for scientific investigations. Crew Tr aining One of the main objectives of the Earth Observations and Photography Experi? ment was to utilize the capabilities of man as a trained observer in orbit. In accordance with this goal, an extensive training program consisting of classroom sessions and flyover exercises was initiated 1 year before the mission. Classroom training was conducted by Earth scientists from various disci? plines. These specialists briefed the astronauts on the types of Earth features they would observe from orbit. The first lectures on geology, hydrology, ocean? ography, desert studies, and meteorology consisted of background on theory and familiarization with terminology. Subsequent lectures were scheduled on the basis of crew interest. Other sessions, conducted mainly by the Principal Investigator, covered 0) operational procedures and viewing conditions and constraints and (2) groundtrack familiarization and specific photographic and observational requirements. The crew received approximately 60 hours of classroom training during 20 sessions. A schedule of the training sessions is given in table 10-IV. The flyover exercises were designed to give the astronauts practical experience in target acquisition and site selection and to familiarize them with the types of features they would observe from Earth orbit. The astronauts were also able to practice verbalizing about and handling onboard equipment, including cameras, lenses, the color wheel, and the tape recorder. Each flyover exercise consisted of a predetermined flight route with a visual observations book designed for that particular flight and similar to the one to be used during the actual mission. Seven high-altitude flyover exercises (table 10-V) were planned over areas of the United States. The California flyover was repeated twice and the Florida flyover once for a total of 10 flyover exercises. During these flights, the astronauts observed both sites scheduled for observation during ASTP and examples of the various types of ocean features and landforms they would view from Earth orbit. These flyovers were valuable in showing the astronauts how to select the optimum conditions for observations and photography. For example, they found that sunglint was especially important in observing ocean features such as currents, eddies, and internal waves. On land, high Sun angles were best for observing color variations, whereas a low Sun angle enhanced relief and facilitated observa? tions of faults and sand dunes. The flyover exercises gave the crew valuable practice in making visual observations and acquiring photographs. 10-3 METHODS AND TECHNIQUES Photographic Systems Three types of imaging systems (video, cameras, and scanners) have been successfully used in Earth-orbital surveys. The ASTP photographs of observation and mapping sites were made with a video tape recorder (VTR), a 70-millimeter Hasselblad reflex camera (HRC), a 70-millimeter Hasselblad data camera (HDC), a 35-millimeter Nikon camera (with exposure control), and a 16-millimeter data acquisition camera (DAC). The 70-millimeter HDC was usually bracket mounted and could accept both 60-millimeter and 100-millimeter lenses. An intervalometer was used, and the frequency of frame usage was calculated to provide stereoscopic coverage with a 60-percent overlap. The HDC was equipped with a reseau plate to improve geometric accuracy and to allow the construction of controlled photomosaics. In general, the photographs obtained with the HDC are excellent, with the exceptions of a few short segments of unplanned photography that were out of focus and one mapping pass over the northeastern United States in which the wrong lens was u~ed. In addition to mapping strips, photographs of approximately 60 observation sites were made using either the hand-held HRC with the 50- or 250-millimeter lens or the HDC. However, most of the visual observation targets were photographed with the HRC. The HRC has a single lens reflex mechanism that allows the astronaut to see what he is photographing. The crew reported that light loss through the 250-millimeter lens made it difficult to locate the target and to center it within a frame. However, all photographs taken with this lens are excellent. The 16- millimeter DAC was used to acquire photographic data over the western Sahara and to provide a sequential film of color zone transitions in the largest sand sea in the wor ld. Real-time television transmissions were also scheduled, and images of the daylight portion of revolution 124 over the Pacific Ocean were recorded on the VTR. These color television images of the Earth are potentially capable of providing new data in poorly studied areas and in areas such as the Pacific Ocean, which is too vast for conventional oceanographic surveys. They can give scientists an astro? naut's perspective of target acquisition and tracking and also provide imagery that can possibly be reformatted for stereographic and radiometric analysis . Thirteen magazines of color film were used for the scheduled mapping sites (type SO-242) and observation targets (type SO-368). The SO-368 film was specially coated with the equivalent of a Wratten 2A filter to improve the color sensitivity of the film by eliminating the effects of short wavelengths. Two maga? zines of type 2443 color infrared film were also used to facilitate identification of features such as volcanic rocks and red tide blooms. 10-4 I I J Visual Observation Aids The human eye-brain system is similar to a camera in that it has a lens and an iris, it generates images with good resolution and geometric fidelity (the resolving power of the unaided human eye is 0.0003 radian or approximately 0.60? (ref. 10-9)), and it is sensitive to electromagnetic radiation in the visible region. Under laboratory conditions, the eye is estimated to be able to distinguish 1 X 7.5 6 color surfaces, a precision that is 2 to 3 times better than most photoelectric spectrophotometers (ref. 10-16). The eye can easily distinguish subtle color variations to a greater extent than any commercially manufactured film, but the brain cannot recall these after a given period of time has elapsed. Real-time calibration of desert and water colors was achieved by the use of a two-sided color wheel composed of carefully selected Munsell colors (fig. 10-2 and table 10-VI). These colors can be compared to the photographs to apprise users of the color sensitivity and fidelity of the film. However, the crew indicated that it was sometimes difficult to make good compari? sons because variable lighting conditions inside the spacecraft often resulted in the color wheel being in the shade. To assist in the acquisition and location of visual observation targets, the use of 20-power binoculars was originally planned: However, after the crew tested the binoculars during flyover exercises, a change was made to use a 16-power monocular. The crew believed the monocular would provide a more convenient means of checking the eye's resolution and of locating targets. During postmission evaluation, the astronauts indicated that the usefulness of the spotting scope was curtailed by the speed with which a target passed outside their field of view. The principal onboard aid was the "Earth Observations Book." This book was divided into three major sections. The first section contained (1) a time line summarizing the visual observation tasks and mapping camera configurations and (2) a stowage list and a review of operational procedures. Information in the second section pertained to specific visual observation targets and was arranged according to site numbers. For each site, there was a summary page with a map showing revolution groundtracks followed by a page (one for each target) that included specific questions, appropriate diagrams and photographs, and camera settings. The last section was a reference appendix that included maps of the distribution of volcanoes , ocean currents, July cloud cover, etc. , and diagrams of various Earth features such as drainage patterns, ocean phenomena, dune types, and faults. Flight Planning Earth observations and photography mission tasks required approximately 12 hours of crew time. These tasks were planned during 24 revolutions and assigned to specific crewmembers. The task assignments for the mapping sites and the visual observation targets are listed in table 10-VII . Planning for the ASTP mission also included simulations of real-time activities. The Earth observations team participated in three mission simulations to practice interaction with other Mission Control Center personnel and with the 10-5 crew. These proved to be very useful exercises because the need existed for verbal communications with the astronauts during the mission. The Earth observations team supported the mission and was in contact with ground-truth data collection parties on a 24- hour basis throughout the mission. RESULTS Ground-Truth Data During the real-time operations of the ASTP mission, the largest air, sea, and ground support team of any manned mission collected ground truth to expedite the postmission interpretation of orbital observations and photography (fig. 10-3). This support included the acquisition of metric and multispectral photography by high-altitude aircraft. Aerial photography was acquired simultaneously during several ASTP photographic passes to link ground-based studies with Earth-orbital observations. Ocean research vessels obtained data on sea surface temperatures, salinity, water color , current directions, and cloud types and heights. On land, ground -truth teams collected data to support geological, hydrological, and desert research projects in India, Guatemala, Mexico, the United States, and Egypt. A summary of the reported support operations follows. ANZUS Eddy (site llD). - The Australian ship Bombard, stationed in the Tasman Sea, surveyed the warm water ANZUS (Australia-New Zealand-United States) Eddy. Oceanographic data indicated that the nearly circular eddy was 145 to 160 kilometers in diameter with surface temperatures 2? warmer than the sur? rounding water. Ship personnel also reported a cumulus cloud formation over the center of the eddy and a number of trawlers fishing for tuna within the eddy. Caribbean (site 7G). - To support crew observations and photography of the extent of organic acid outflow from the Orinoco River, the Bellairs Research Institute of McGill University sponsored three cruises from the island of Barbados on July 21, 22, and 23. Observations and measurements were made of sea state, water color, sea surface temperature, salinity, chlorophyll content, cloud cover, and wind speed and direction. Egypt (sites 9E and M7). - For the revolution 71 mapping pass over Egypt, geologists from the Ain Shams University in Cairo will provide ground-truth data to be used in support of a photogeological investigation of the Western Desert of Egypt. Field work will be carried out at Abu Rawash, Oweinat Mountain, and the Faiyum, Bahar1ya, and FarMra Oases (fig. 10-4). Ground investigations include detailed mapping, characterization of the structural and topographic setting, and studies of desert erosion patterns and grain transportation. The major objective is to use the geological data in verifying color zonation and other features recorded on the AS TP film. England (sites 6A and 6B). - The Royal Air Force flew a 3- day sequence over ocean waters off southern Ireland and England. Expendable bathythermo? graphs (XBT's) were dropped from the planes to provide data on water temperature as a function of depth. 10-6 J Gulf of Mexico (site 5A). - The National Oceanic and Atmospheric Adminis? tration (NOAA) research vessel Virginia Key made a transect of the Gulf of Mexico from Miami to the Yucatan peninsula and obtained data on the location of the Gulf Loop Current. Approximately 20 NOAA ships were also stationed around the Mississippi River Delta. New Zealand (site 1). - The Royal New Zealand Air Force flew P-3 airplanes along the revolution 17 groundtrack starting from East Cape , New Zealand, then north-northeast over the Pacific Ocean to obtain photographic data and to plot cloud types and heights. A New Zealand Navy research vessel made a transit along the same line and acquired oceanographic data, including water temperatures and sound velocity measurements. Strait of Gibraltar (sites 9K and 9J). - The U . S. Navy research vessel Kane obtained oceanographic data along a line paralleling the revolution 73 groundtrack from the Canary Islands to Spain. These data were obtained to support crew observations of a current boundary extending north and south off the western coast of Portugal. The Navy also flew a P-3 aircraft along this line dropping XBT's. East of the strait in the Mediterranean Sea, the carrier U . S . S. Kennedy obtained oceanographic and meteorological data. United States (sites 2A, 4A, 4B, 5B, 5E, and 5F). - Several high-altitude flights were flown over the United States with a B-57 aircraft based at the NASA Lyndon B. Johnson Space Center and a U- 2 aircraft based at the NASA Ames Research Center. Metric and multispectral photography was obtained with a metric RC-10 camera and a multispectral Vinten System A camera. Sensor data are pro? vided in t able 10-VIII. Photographic coverage was acquired over the East Coast (coastal areas of New York, Massachusetts, and Maine), Florida (coastal areas) , the northwestern United States (Washington, Idaho, and Oregon), and the south? western United States (from Kingman, Arizona, to Santa Maria, California). In addition to the aircraft support, ocean research vessels made measure? ments in the Gulf Stream and along the New England coast. The U.S.S. Preserver collected data in the Gulf Stream north of Jacksonville, Florida, on the distribution, size, and velocities of eddies. The ship also released four drifting buoys that had transmitters to the Nimbus-F satellite. The buoys were positioned about once a day throughout the mission and provided data on current direction and velocity. In New England, two Bigelow Laboratory research vessels (the Bigelow and the Challange) made a traverse of the Gulf of Maine from Portland to the Bay of Fundy and also southward to Cape Cod. Data were obtained on the size, shape, and location of red water patches due to toxic phytoplankton and included measurements of sea surface temperature, salinity, chlorophyll content, and water color. In addition to the red tide observations off the coast of Maine, support ships and sampling stations of the Commonwealth of Massachusetts acquired water color, salinity, and biological content data. A high chlorophyll content in the coastal waters off New England was reported and was possibly the result of abnormally heavy rains carrying an increased amount of biota into the sea. 10-7 Mission Data A total of 11 mapping passes and 60 visual observation sites was scheduled. Only one mapping pass was canceled (on revolution 15/16) because of problems in th e Flight Plan. Approximately 20 percent of the 100 planned observations of the 60 sites were not performed because of bad weather, making the overall success measure of the experiment approximately 80 percent. The summary results of the photographic mapping sites and the visual observation targets are given in tables 10-IX and 10-X, respectively. DISCUSSION The quality of photographic data obtained in previous Earth-orbital surveys has firmly established their value as basic tools in the evaluation of terrestrial features and in the reconnaissance of remote locations. Before the ASTP mission, several types of photographic systems were successfully used in spacecraft. On the Skylab missions, the Earth resources experiment package included a multi ? spectral array of six cameras (with various film/filter combinations in the visible and infrared) as well as a high-resolution Earth terrain camera. Two of the more obvious advantages of such orbital systems over aerial photography are the large regional coverage and the speed with which data can be obtained. These advantages facilitate the preparation of base maps because mosaics of large areas can be rapidly prepared with orbital photographs. The ASTP planning for visual observations and photography utilized these advantages to their maximum. For example, several mapping passes were scheduled over areas where general land surveys (including a classification of terrain, mineral resources, and land use) are either nonexistent or inadequate. Targets were also selected for photography in oceans and deserts, where size and inaccessibility make conventional surveys impractical. The large regional coverage of orbital photographs also provides a more efficient method for the observation of large-scale phenomena, such as color tran? sitions within deserts and ocean currents. Orbital photographs have a greater perspective and are useful in the study of broad distributions and regional structure; two examples are major fault zones (such as the San Andreas system and the Levantine Rift) and snow cover and drainage patterns (as in the Cascade Mountains). One other advantage is the stability of spacecraft as a platform for Earth-looking photography. Variations in velocity and attitude are minimal and flightpaths can be determined with great precision. The following is a discussion of some of the ASTP tasks and results in the fields of Earth science selected for emphasis on this mission. Geology Geological investigations on the ASTP mission included observations of major active fault zones, river deltas, volcanoes, and astroblemes (ancient impact scars). Studies of global tectonic patterns were made by observation and photog? raphy of some major areas of continental crustal fracturing. One of these areas 10-8 L ___ j I I was the Levantine Rift, a fault complex formed as a result of the motion of the Arabian subplate. The crew was asked to observe the northern extensions of this rift and to obtain photographs necessary to an understanding of the locations and mechanisms of displacement. Excellent photographs were obtained of the entire area (e. g. , fig. 10-5). The photographs support the theory that motion of the Arabian subplate is counterclockwise drift rather than eastward rotation. Astronaut observations of the area provided additional data: The one thing I noticed was that if you look at the 9G map [fig. 10-6], the dotted line on the left up near the end of it, makes a bend to the left and follows a new tectonic line or fault which goes along parallel to the Turkish coast. In other words, the one on the left, number 1, goes up . . . and then makes a left turn and parallels the Turkish coast. Two seems to be obscured and it just ends in a lot of jumbled country up somewhere slightly beyond where the number 2 is, and it seems to end right in this jumbled area. Three, I could trace clear up to a river which - I'll have to see a map later. But I could trace the faults out, going rather eastward. You could see them through the valley silt, clear up to a river which must be inland in either Syria or Turkey. So the overall pattern of these is a fan; three going. almost eastward, and one bending finally to the north, and two going to the northeast . (CMP) Photographs of river deltas were also acquired. In the geologic record, deltaic sediments are often a source of natural gas and oil accumulation; an under? standing of the growth of deltas might have applications in the future development of these resources. Several major river deltas were photographed, including the Orinoco (fig. 10-7), Rhone, Nile (fig. 10-8), Fraser, Danube, and Yellow Rivers. These photographs will be compared with previous orbital photographs in an effort to document the rate and direction of growth of modern deltas. A study was also made of astroblemes, or ancient impact scars, to increase knowledge of the interaction of the Earth and meteoritic bodies and to locate new areas for possible economic exploitation. Photography of this type of feature was obtained in Libya near the Kufra Oasis (fig. 10-9). Resolution was excellent. The central dome and ghost ring of one known feature, the BP structure, were easily recognized. Another circular feature, possibly a twin site, was also identified. Oceanography In the field of oceanography, a study was made of major ocean features such as eddies, currents, and internal waves. Because large areas can be rapidly surveyed, the global view of oceans from space is especially useful. As previously stated, extensive ground-truth data collection (fig. 10-3 ) was coordinated with 10-9 photographic passes to aid in postmission data interpretation. Areas of prime scientific interest include the following . Area Coral Sea ANZUS Eddy Caribbean Sea Gulf of Mexico Mediterranean Sea Interest Interaction of currents with the Great Barrier Reef Eddies in the Coral Sea Support of an Australian-New Zealand-United States oceanographic study of a 200-kilometer-wide eddy east of Sydney, Australia Ocean currents and their relation to fisheries Eddies and their relation to the Gulf Stream Development of the Gulf Loop Current Eddies and currents in the Yucatan Channel Observation and photography to support oceano? graphic study by U . S. Sixth Fleet research team Effects of reduction of freshwater from the Nile River Investigations of these features will provide a better understanding of dynamic ocean phenomena and will have potential applications to trade, shipping, and the identification of environmental parameters affecting fisheries. The crewmen remarked that the ease with which oceanographic targets were discerned was a function of several factors; Sun glitter was identified as the most in fluential parameter. For example, the following remarks concerned the visual identification of internal waves west of the Strait of Gibraltar (fig. 10-10): I was looking for al1 these things and suddenly they popped out within a second right there. Just suddenly when the Sun angle changed, everything was there, the waves and the boundary were all there and we just snapped a series on them. But before that, there was nothing but just solid blue water and then they just suddenly popped ... You have to be ready and the Sun angle has to be just right. And it's there for just a short period of time and then it's gone. (ACDR) A study was also made of red tide occurrences off the New England coast. The crew was informed during the mission that support ships off the coast of Maine had located a zone of discolored water near the mouth of the Damariscotta River. This area was observed by the crew, and the DMP later reported: 10-10 Per ground request we just shot a few frames here up through the New England area ending on magazine CX-10 with frame 35. Trying to pick up the red tide around Boothbay , and we did see a lot of red coloration in the water there. However, some of it ~l I I looked to me like it was coming out of the river mouths and is really sediment. And I hesitate to term it red tide. We shot some pictures; maybe we can psych it out later. Examination of the returned photographs suggests that the DMP photographed the area of the Bay of Fundy (fig. 10-11). This area shows the same features that were expected around Boothbay Harbor, mainly discolored reddish water caused by sediments from coastal rivers . To aid oceanographers in the identification and location of ocean features, the crew was asked to provide the ground-elapsed time (GET) when a target was observed. However, during the postmission debriefings , the crew indicated that time was probably insufficient to identify the exact location of an observed ocean site because they could see such a broad area . Desert Studies Deserts occupy nearly one-sixth of the Earth's land masses, but first - order surveys of most desert regions are inadequate. Size, remoteness, and inaccessi? bility make conventional aerial surveys impractical and costly. Photographs acquired from space, however, can provide reliable data that are useful in the preparation of base maps and in the evaluation of eolian landforms. Orbital images of large areas can be rapidly acquired for the construction of mosaics and for distribution analysis of large-scale phenomena such as color variation and sand dune patterns. As part of the ASTP investigation of deserts and arid lands , visual observations and photography of the following types of features were scheduled. Feature Eolian landforms Desert color Processes of desertification in the Sahel Interest Dune shape, size, and distribution Dune patterns and their relation to topography , wind, moisture, and vegetation Color transitions within a homogeneous desert Comparison of equatorial desert color with that of high -latitude deserts Land use Evolution of dune patterns and effect on cultivation Excellent photographs of deserts in Africa, the Arabian Peninsula, Australia, and Argentina were acquired. Photography over the Sahara is extensive and includes two mapping passes over Algeria, Chad, Libya, and Egypt; a strip of 16-millimeter photography over the western Sahara; and numerous hand-held photographs. This photography will be used in an investigation of eolian geomor? phology primarily to evolve a classification scheme for deserts in North Africa. In 10-11 addition, a mosaic to be constructed from the mapping photography of Egypt will be used in a study of the Western Desert of Egypt by a team of geologists from Ain Shams University, Cairo. Synoptic photography and astronaut observations also provided valuable information on desert color. Deserts often contain a significant amount of iron compounds that, because of weathering, oxidize into red-colored ferrous oxides. Photography of color zonation within a desert where the sand is derived from the s ame source (e. g. , fig. 10-12) can be used to determine relative age. The crew used the color wheel to calibrate variations in the color of North African sand seas. During photography of the western Sahara with the 16-millimeter DAC, the DMP made the following observation: We discovered a large expanse of fairly homogeneous sand desert. No obvious dune patterns ... We're now coming to the rocky volcanic hills of the northeast edge of the big sand desert. Some very red sand to the north. In fact, it looks almost like a massive parabolic sand dune, black with red sand behind it. And we're coming up on a large band of very black barren-looking hills with great red areas interspersed between them . . . Okay, and at 119: 50, we're coming up into a couple of areas where the dunes are now a little better defined; they look like old doIlies. They're certainly not stars and they're not linear either. And we get farther into the north, there is a little linear pattern, but it's mostly of dome appearances , very homogeneous. Excellent photographs of the Simpson Desert in Australia were also obtained (e. g . , fig. 10-13). Visual observations were made on several passes over the area, and the crew was able to identify dune patterns and desert color. We're going over the Simpson Desert right now. And it's just fantastic. It's got dunes in it, looks like they are very long, and they look like road tracks, there are so many of them - like hundreds of parallel road tracks, it's just plain spectacular. (CMP) Yeah, and the long red streaks are matching about color 10, I would say on [the color] wheel and some of those long sand streaks, could have either gone to the 9, between 9 and 10, about like 9A. (ACDR) In Argentina, the crew photographed a little-know!). dune field (fig. 10-14) and made visual observations of dune shape and the relation of the dune field to the surrounding topography. The following is an excerpt from the discussion of this occurrence during the postmission crew debriefings. 10-12 ACDR Okay, it's right over the edge of the Andes Mountains ... And you could really see how they were crescents; it looked like occasionally maybe the head of the crescent would wash out, and it would tend to be a linear one with lineations on the side. There are all those other little crescents up on the left. That was the area that you wanted me to look at? PI Yes, that's the only one that we thought existed. We didn't know that there were two dune fields. ACDR I'd remembered that there was some type of linear feature. There were two rays. One was on this edge down here, which is nearly linear. But the big thing was those huge crescents; then something else linear caught my eye. I see what it is now, those very minor ones in the center left part of the picture. Co-I This is a particular variety that I haven't seen anywhere else. I have seen a lot of varieties of this generally crescentic dune pattern, but nothing where you have these linear dunes superimposed right on the crescent and they're oriented in this way. That's totally unlike anything I have ever seen anywhere else, so this really is the prize picture as far as desert dune observations went. ACDR On that little field up there, it's just the way the boundary was very well defined, as opposed to the other where this kind fades out into like a dry lake bed. Co-lOne of the things that is very obvious is the relationship between the edge of the alluvial fan and the beginning of the dune fields; it's very, very sharp. That's not a very red dune field, is it? ACDR No, it's not. Co-I Does it look about like the ones you see in the southwestern United States in terms of color? DMP I would say so. We had a fairly early morning light. ACDR I think it's close. We have early morning light there and low Sun angles. It didn't have the redness like the Simpson does or anything like that. Hydrology Hydrological investigations included photography of snow cover and drainage patterns as well as visual observations of glaciers, firn lines, and closed water basins. Mapping of snowpack distribution is important in the estimation of the 10-13 volume of water reaching drainage systems for use in irrigation and the control of floods. Targets for snow cover photography included the Cascade Mountains in the northwestern United States (fig . 10-15), the Andes Mountains in South America, and the Himalaya Mountains in southern Asia. Coverage of the Cascades and Andes was acquired; however, the Himalayan photography was not successful because of cloud cover. Visual observations of glaciers and firn lines were also scheduled to test the limits of the eye's resolution. The crew was successful in distinguishing firn lines and remarked that this was a function of both texture and color. The following remarks were made during the postmission debriefings. CMP The best case, I believe, was in the Alberta- British Columbia area. I very easily saw a firn line on one big glacier up there. PI How did you make the distinction? Why do you think you were able to see that? Because of color or texture? CMP Texture and color and even shininess, you might say. Surface texture, I guess. PI The ice being more gray? DMP Kind of a gray compared to pure white. ACDR Yes, it goes from white to gray. And the firn line wasn't just a straight line; it was kind of jagged. It wasn't a clear line. DMP But I thought I could see texture down below it also, that sort of looked like flow patterns going parallel with the glaciers. A study was also made of major lakes including Lake Chad, the Great Salt Lake, Lake Eyre, and the Caspian Sea. Lake Chad, once one of Africa's largest lakes, lies in the Sahel region between the savanna land and the sandy desert. To the northeast, it is bounded by fossil dunes; from the south, tropical rivers flow into the lake, bringing sediment and freshwater. The rapid decrease in lake size has been attributed to three factors: the influx of sand from the Sahara, the accumulation of sediments deposited by inflowing rivers from the south, and the evaporation of surface waters. The possibility that Lake Chad might eventually dry up presents a problem because the southern part of the lake is biologically productive and rich in fish. The ASTP photography will be compared to Skylab data to determine the rate of change in the size of Lake Chad. Many more dunes are now visible within the lake (fig. 10-16). 10-14 I I J I I I The ASTP photography of the Great Salt Lake in the United States will also be compared to Skylab imagery. Construction of a railroad causeway in 1956 has essentially divided the lake into two basins. Almost 90 percent of the lake's inflow now enters the southern half, resulting in a rise in water level and a decrease in salinity in that half. Conversely, waters in the northern basin have become oversaturated with salts and minerals. This change in salinity is easily detected from orbit because the presence of different types of algae has given each half a different color. These factors have had a serious effect on both the ecology of the lake region and industrial development. Meteorology Meteorological investigations were made in a study of cloud features and tropical storms. Photography of cloud features includes Benard cells, Karman vortices, mountain waves (rotor clouds), atmospheric bow waves in the lee of islands, and cumulonimbus buildups . The crew also obtained photography of a developing tropical storm in the Caribbean Sea. The following is an excerpt of real-time observations over the storm: It doesn't seem to cover so much area, but it does have a rather swirling "V" appearance. I don't see an eye, but I can see where an eye would be . (CMP) Photographs and visual observations will help meteorologists develop com? puter models of hurricanes and tropical storms. Stereophotographs of a dissipating storm were also taken and will be used in making a three-dimensional stereoscopic model of the storm to help decipher its "topography." The stereoscopic model in turn will affect theoretical models of storm development and dissipation. Excellent photography of thunderstorms was also acquired and will be used in studies of severe storm development (fig. 10-17). Unusual photographs of large-scale intersecting cloud streaks were obtained (fig. 10-18). During postmission debriefings, the crew reported that these features were too large to be contrails and had a wedge-shaped appearance: DMP We saw an awful lot of contrails over the North Atlantic and it's nothing like that. They just don't get that big. CMP Contrails were lines; these are wedges practically. QUERY Remember from Skylab, when they took a picture and they thought it was the hot air coming from a ship going through a very low scattered deck about like that, and there was a plume going right across the apparent trend of the clouds. Do you think that maybe that was this same thing? CMP It's a possibility, I suppose, but at the time it looked natural. 10-15 Environmental Studies Environmental investigations included photography of sources of atmospheric and water pollution and potential sites for sea farming. The crew recognized and observed several different sources of atmospheric pollutants, both manmade and natural. These sources included volcanic plumes, duststorms in the Sahara and the U . S . S . R . , brush fires in Africa, oil fires in the Middle East, ship trails, and contrails. Astronaut observations were useful in determining the extent and geo? graphic locations of these features. Sources of water pollution include suspended sediments, oil spills, and or ganic compounds. The occurrence of two types of water pollution was documented with photography of the Orinoco River Delta (fig. 10-7). In addition to sediments, the Orinoco River outflow includes a high concentration of humic compounds that result in the discoloration of the ocean waters for hundreds of kilometers. The ASTP information, combined with real-time ground-truth data collection, will allow a better understanding of this phenomenon and its effect on local fisheries. In cooperation with the International Maritime Commission, observations of oil slicks in North Atlantic ship routes were planned, but cloud cover and the lack of sunglint prevented the acquisition of data. However, observations were made and photographs were taken of oil slicks in the Mediterranean Sea and the Persian Gulf. The crew was also asked to observe and photograph several areas designated by Jacques Cousteau as potential sites for "sea farming." Three sites were sched? uled in real time and included the Adriatic Sea, the waters south of Cuba, and the Strait of Georgia. CONCLUSIONS Preparation and execution of the ASTP Earth Observations and Photography Experiment was a highly rewarding experience. The many hours spent in training the crew, both in flyover exercises and in the classroom, brought significant results that attest to the value of man in space flight. The astronauts are enthu ? siastic about their contributions, and the participating scientists have a consider? able amount of new data to be interpreted and analyzed. This analysis will further our vistas in numerous fields of Earth science. From the results of this experiment, several conclusions can be drawn in r egard to the most tangible scientific results and the role of man in space. Tangible Scientific Results Evaluation of the scientific return of ASTP observations of the Earth has just begun. It is difficult, at this stage, to determine the most significant contributions. The following are only examples of what has been learned in the considered fields of Earth science. 10-16 Geology. - Although many fault systems were studied from orbit, the obser? vations and photographs of the Levantine Rift zone are most prominent. Three major faults were traced to their northernmost extremities where very little was known about them. These faults appear to branch out in north and northeast directions. Branching appears to start at a pivot point for the counterclockwise rotation of the Arabian crustal subplate relative to the African crustal plate. This indicates that fractures in that zone are not simply the result of a rip-apart motion but a complex rotation of the entire Arabian peninsula. The results of detailed mapping of these faults from the ASTP data will add significant insight into the tectonic regime of the Middle East. Oceanography. - One of the most significant ASTP findings establishes that ocean features such as eddies and internal waves are more common than previously thought. The ASTP crew also established that viewing direction, as well as Sun angle, is extremely significant in observing internal waves. Viewing conditions will be thoroughly documented to allow better planning and preparation for similar activities in the future. Deserts. - Perhaps the most significant contribution of the experiment is that the ASTP data will help define (1) relative ages of desert areas based on color and (2) direction of desert growth using sand dune patterns in North Africa. The implications of these results, particularly to the Afri"can drought problem, include the ability to distinguish, from photographs, areas of recent desert formation and to establish the directions of desert growth. Also, two new unique patterns of dune morphologies were observed: star dunes atop linear dunes in the Gobi Desert and a fish-scale pattern of dense sand dunes overlain by thin linear dunes in Argentina. Hydrology. - Snow cover over the Cascade Mountains was photographed on separate days to permit studies of melt patterns. These photographs will also be compared to previous images of the same area to establish trends in snow accumu? lation and melting for hydrological projects. Meteorology. - The most significant result in the field of meteorology appears to be the photography of a developing storm northeast of Florida and of a dissipating storm over the Atlantic Ocean. Stereoscopic models of these storms will be studied to improve theoretical models of tropical storm development and dissipation. Environment. - The outflow of the Orinoco River into the Atlantic Ocean was described, and the observations were documented with photographs. In addition to sediments, the Orinoco River outflow includes an unusually high concentration of humic compounds that result in the discoloration of the ocean waters for hundreds of kilometers. The ASTP information combined with real-time ground-truth data collection will allow a better understanding of this phenomenon. Role of Man in Space From the ASTP experience, the following conclusions may be made. 1. Man in space can help design instruments or film to be used on unmanned probes. An example is the use of a color wheel to establish the actual range of visible colors of deserts and oceans. 10-17 2 . A trained observer is probably essential to the study of features and phenomena characterized by transient visibility. An example is internal waves that are visible only under very restricted conditions. 3. An observer in orbit can make immediate interpretations that significantly contribute to solving the problem under investigation; for example, the explanation of the tectonic setting of the Levantine Rift area. 4. A human observer is essential if the purpose of the study is to explore the unknown. A trained observer will scan an entire region and select targets for photography that will draw attention to the significant aspects. 5. From the information learned about deserts on this mission, it is concluded th at much more can yet be attained from orbital surveys in this field. Desert study will also be important in comparative planetological studies; many of the features of Mars are similar to those of the Earth's deserts. 6. Earth observations and photography tasks require a flexible platform where viewing angles and interior lighting conditions can be controlled. The design of instrumentation should allow control of imaging systems by the observer. 7. For the successful performance of Earth observations tasks, the observer must be well prepared and well trained. The exercise must be pursued systemat? i c ally; otherwise , significant features and phenomena may be overlooked. 10- 18 REFERENCES 10-1. Earth Photographs From Gemini III, IV, and V. NASA SP-129, 1967. 10-2. Earth Photographs From Gemini VI through XII. NASA SP-l71, 1968. 10-3. Cortright, Edgar M. , ed.: Exploring Space With a Camera. NASA SP-168, 1968. 10-4. Lowman, Paul D. , Jr.: The Third Planet. Weltflugbild. Reinhold A. Muller (Zurich, Switzerland), 1972. 10-5 . Musgrove, R. G.: Lunar Photographs From Apollos 8 , 10 , and 11. NASA SP-246, 1968. 10-6. Kopal, Zdenek: A New Photographic Atlas of the Moon. Taplinger Publishing Co. (New York), 1971. 10-7. El-Baz, Farouk: New Geological Findings in Apollo 15 Lunar Orbital Photog? raphy. Proceedings of the Third Lunar Science Conference , vol. 1, MIT Press (Cambridge, Mass . ), 1972, pp. 39-61. 10-8. El-Baz, Farouk; and Roosa, S . A.: Significant Results From Apollo 14 Lunar Orbital Photography. Proceedings of the Third Lunar Science Conference, vol. 1, MIT Press (Cambridge, Mass.), 1972, pp. 63-83. 10-9. El-Baz, Farouk; and Worden, A. M.: Visual Observations From Lunar Orbit. Sec. 25, Part A, of the Apollo 15 Preliminary Science Report. NASA SP-289, 1972. 10-10. El-Baz, Farouk; Worden, A. M.; and Brand, V. D.: Astronaut Observations From Lunar Orbit and Their Geologic Significance . Proceedings of the Third Lunar Science Conference, vol . 1, MIT Press (Cambridge, Mass.) , 1972, pp. 85-104. 10-11. Mattingly, T. K.; El-Baz, Farouk; and Laidley, Richard A.: Observations and Impressions From Lunar Orbit. Sec. 28 of the Apollo 16 Preliminary Science Report. NASA SP-315, 1972 . 10-12. Mattingly, T. K.; and El-Baz, Farouk: Orbital Observations of the Lunar Highlands on Apollo 16 and Their Interpretation. Proceedings of the Fourth Lunar Science Conference, vol. 1, MIT Press (Cambridge , Mass.), 1973, pp. 49-56. 10-13. Evans, R. E.; and El-Baz, Farouk: Geological Observations From Lunar Orbit. Sec. 28 of the Apollo 17 Preliminary Science Report. NASA SP-330, 1974. 10-19 10-14. El-Baz, Farouk; and Evans , R. E.: Observations of Mare Serenitatis From Lunar Orbit and Their ? Interpretation. Proceedings of the Fourth Lunar Science Conference, vol. 1, MIT Press (Cambridge, Mass.), 1973, pp. 139-147 . 10- 15. Kaltenbach, J . L.; Lenoir , W. B.; McEwen, M. C .; Weitenhagen, R. A.; and Wilmarth, V. R . , eds.: Skylab 4 Visual Observations Project Report. NASA TM X- 58142 , 1974. 10-16. Committee on Colorimetry: The Science of Color. The Optical Society of America (Washington, D. C.), 1963 ', p. 129. 10-20 L ____ -1 I 1 Name J . R. Apel J. C. Barnes a P. G. Blacka G . Borstad C. S. Breeda N. S . Brill W. J. Campbella R. Citron J. Cousteau R. Dietza L. Dunkelman F. EI-Bazb G. Ewing R. K. Holz W. A. Hovis R. C. Junghans J. L. Kaltenbach TABLE 10-1.- EARTH OBSERVATIONS TEAM Discipline Oceanography Snow mapping Meteorology Oceanography Deserts Red tide Hydrology Short-lived phenomena Sea farming Marine geology Atmosphere General Oceanography Demography Oceanography Environment Skylab results Affiliation National Oceanic and Atmospheric Administration (NOAA) Environmental Research and Tech? nology, Inc. NOAA Bellairs Research Institute, McGill University, Canada Museum of North Arizona and U. S. Geological Survey (USGS) Commonwealth of Massachusetts University of Puget Sound Smithsonian Institution Cousteau Society NOAA University of Arizona and Goddard Space Flight Center (GSFC) Smithsonian Institution Woods Hole Oceanographic Institute University of Texas at Austin GSFC NOAA Lyndon B . Johnson Space Center (JSC) W. B. Lenoir . Skylab results JSC N. H . MacLeod G. A . Maula M. C. McEwen E. D. McKee a S. McLafferty D. A. Mitchell J. A. Murphy W. R. Muehlberger a aCo-Investigator. bprincipal Investigator. Deserts and Agriculture American University Oceanography NOAA Skylab results JSC Deserts USGS General Smithsonian Institution General Smithsonian Institution General Smithsonian Institution Geology University of Texas at Austin 10-21 Name K . M. Nagler D. K. Odell D . M. Pirie P . R . Pisharotya D. E. Pitts R. O . Ramseier J. W. Sherman L. T . Silver a R . E. Stevenson a F . M. Suliman G. A. Swann V. R . Wilmarth R . Wolfe S. P . Vonder Haar C . Yentsch a M. Youssef aCo-Investigator. 10- 22 TABLE 10-1.- Concluded Discipline Weather patterns Oceanography Oceanography Hydrology Color Science Hydrology Meteorology Geology Oceanography Deserts Geology Skylab results General Oceanography Red tide Deserts Affiliation NOAA University of Miami Army Corps of Engineers, California Indian Space Research Organization (lSRO) , India University of Houston Department of the Environment, Canada NOAA California Institute of Technology Scripps Institute of Oceanography College of Education, Qatar USGS JSC Smithsonian Institution University of Southern California Bigelow Laboratory, Maine Ain Shams University, Egypt I ! TABLE 10-11.- PHOTOGRAPHIC MAPPING SITES Site Name Objective Ml Gulf Stream The Gulf Loop Current and the Gulf Stream from eastern Florida to its confluence with the Labrador Current M2 New Zealand The Alpine Fault in South Island and the coastal waters between the two islands and north of North Island M3 Southern California Coastal waters off California, the San Andreas Fault system, and the Mohave Desert M4 Himalaya Mountains Ocean features in the Indian Ocean and Arabian Sea, the flood plain of the Indus River, drainage patterns, and snow cover in the Himalayas M5 Arabian Desert The Afar Triangle, dune patterns in Ar-Rub Al-Khali, and coastal processes at Doha, Qatar M6 Australia Dune patterns and erosional features in the Simpson Desert, the Great Barrier Reef , and eddies in the Coral Sea M7 African drought Vegetation and land use patterns in the Sahel, desert colors in northeastern Africa, the Nile River Delta, and the Levantine Rift M8 Falkland Current The Falkland Current and its confluence with the Brazil Current east of South America M9 Sahara Vegetation and land use patterns in the Sahel, desert colors and dune patterns in the Sahara, and the coastal waters off Tripoli Ml0 Northern California Coastal waters off northern California and subsystems of the San Andreas Fault Mll New England Eddies and gyres in the Gulf of Mexico, the Mississippi River Delta, Chesapeake Bay, and coastal waters off New England 10-23 Site no. I 2 3 4 5 6 7 10-24 TABLE 1O-I1I.- VISUAL OBSERVATION TARGETS Target Site no. Target New Zealand 8 Southern South America 8A Falkland Current Southwestern United States 8B Chilean Andes 8C Dune field 2A Southern California 8D Parana River 2B Baja California 8E Circular structures 2C California Current 2D Great Salt Lake 2E Guadalaj ara 9 Africa and Europe 9A Afar Triangle Weather Belt 9B Arabian Peninsula 9C Guinea Current 3A Cloud features 9D Desert colors 3B Tropical storms 9E Oweinat Mountain 3C Hawaii 9F Nile Delta 3D Kuroshio Current 9G Levantine Rift 9H Niger River Delta 91 Algerian Desert Northern North America 9J Tripoli 9K Strait of Gibraltar 4A Snow peaks 9L Alps 4B Puget Sound 9M Danube Delta 4C Superior iron 9N Anatolian Fault 4D Sudbury nickel 90 Volcanics 9P Bioluminescence Eastern North America 10 Africa and India 5A Gulf of Mexico 5B Gulf Stream lOA Great Dike 5C Labrador Current lOB Somali Current 5D Central American 10C Arabian Sea structures lOD Himalaya Mountains 5E Florida red tide 10E Takla Makan Desert 5F New England red tide 5G Chesapeake Bay 11 Australia Northern Atlantic l1A Playas 11B Coral Sea 6A Oil slicks 11C Simpson Desert 6B London lID ANZUS Eddy Northern South America 12 Antarctican ice 7A Humboldt Current l2A Icebergs 7B Nazca Plain 7C Internal waves 7D Peruvian desert 7E Orinoco River Delta 7F Galapagos Islands 7G Caribbean Sea l I I I I ,--- TABLE 10-IV.- CLASSROOM TRAINING Date Subject Aug. 5, 1974 Plan for Earth observations and photography Aug. 16 Global tectonics and astroblemes Oct. 10 Background, terminology, and Skylab 4 results (oceanography) Oct. 18 Snow and ice Nov. 6 Southwest U. S. tectonics Site selection procedures Nov. 15 Ocean currents and eddies Sites for observation Dec. 3 African rift system and Central Dec. 20 Jan. 7, 1975 Jan. 31 Mar. 5 Mar. 18 Mar. 19 Apr. 1 Apr. 9 May 20 June 2 June 20 July 8 July 13 America Deserts .and sand dune patterns Cloud features and tropical storms Groundtracks and sites Onboard site book Visual observation sites Ocean observation tasks Groundtracks and sites Groundtracks and sites Review of observation tasks Review of observation tasks Review of observation tasks Review of observation tasks Review of observation tasks Lecturer F. EI-Baz R. Dietz S. P. Vonder Haar J. C. Barnes, W. J. Campbell, and R. o. Ramseier L. T. Silver F. EI-Baz G. A. Maul R. E. Stevenson and G. Ewing W. R. Muehlberger E. D. McKee and C. S. Breed P. G. Black F. EI-Baz F. EI-Baz F. EI-Baz Oceanography Team F. EI-Baz F. EI-Baz F. EI-Baz F. EI-Baz F. EI-Baz F. EI-Baz F. EI-Baz 10-25 TABLE lO-V.- FLYOVER EXERCISES Flyover Observation targets Houston to Los Angeles Texas coastal plain Karst topography Basin and range topography Volcanic features Sonora and Mohave Deserts (site 2A) San Andreas Fault system (site 2A) California San Andreas Fault (site 2A) Garlock Fault (site 2A) Desert varnished hills (site 2A) Sand dunes in the Algodones Desert Ocean features in waters off California (site 2A) Gulf Coast Coastal sediments Mississippi River Delta Gulf Loop Current (site 5A) Red tide off the western coast of Florida (site 5E) Florida Gulf Stream (site 5B) Red tide (site 5E) East Coast Gulf Stream (site 5B) Sediment and pollution in Chesapeake Bay (site 5G) Internal waves Sand dunes on Cape Cod Red tide off Massachusetts and Maine (site 5F) Southwestern United States Dune patterns at White Sands and Great Sand Dunes National Monuments Circular structures in the San Juan Mountains Copper mines Northwestern United States Fault systems in northern California (site 2C) Metamorphic foothills of the Sierra Nevadas (site 2C) Snow-covered peaks in Washington (site 4A) Blue Glacier and Southern Cascades Glacier Sediments in Puget Sound "-l I I I I I I j TABLE 10-VI. - MUNSELL COLOR DESIONATIONS a OF THE ASTP COLOR WHEEL Color Desert colorsb Color Ocean colors c wheel no. wheel no. A B A B 1 2 . 5R 6/ 6 2.5R 7/ 8 28 lOBO 4/4 lOBO 5/6 2 2 . 5R 5/ 8 2.5R 6/10 29 lOBO 5/4 lOBO 6/6 3 5R 4/ 10 5R 5/ 12 30 l OBO 6/4 lOBO 7/ 6 4 5R 5/8 5R 6/ 10 31 2 . 5B 6/6 2.5B 7/8 5 5R 6/ 6 5R 7/ 8 32 2.5B 5/6 2.5B 6/8 6 7.5R 6/6 7 .5R 6/ 8 33 2.5B 4/6 2.58 5/8 7 7.5R 5/ 8 7. 5R 6/10 34 58 4/4 5B 5/ 6 8 7.5R 4/10 7.5R 5/ 12 35 5B 5/4 5B 6/6 9 lOR 4/ 8 lOR 5/10 36 5B 6/4 5B 7/6 10 lOR 5/6 lOR 6/ 8 37 7.5B 6/6 7 . 5B 7/8 11 lOR 6/ 4 lOR 7/6 38 7.5B 5/6 7.5B 6/8 12 2 . 5YR 7/ 6 2.5YR 8/8 39 7.SB 4/6 7 . 5B 5/8 13 2.5YR6 / 8 2.5YR 7/ 10 40 lOB 4/8 lOB 5/10 14 2.5YR 6/ 10 2.5YR 6/ 12 41 lOB 5/6 lOB 5/8 15 5YR 5/8 5YR 6/ 10 42 lOB 6/ 6 lOB 6/8 16 SYR 6/ 6 SYR 7/ 8 43 ~.SPB 5/6 2.5PB 6/ 8 17 7.5YR 6/6 7.5YR 7/8 44 2 . 5PB 4/6 2 . 5PB 5/8 18 7.5YR 5/8 7 .5YR 6/10 45 2.5PB 3/6 2.5PB 4/8 19 10YR 5/6 10YR 6/ 10 46 5PB 3/8 5PB 4/1 0 20 10YR 6/6 10YR 7/ 8 47 5PB 4/8 SPB 5/10 21 10YR 7/4 10YR 8/6 48 SPB 5/ 6 5PB 6/8 22 2.5Y 8/6 2.5Y 8.5/6 49 7 . 5PB 5/8 7 . 5PB 6/10 23 2.5Y 8/4 2.5Y 7/ 4 50 7.5PB 4/ 10 7 . 5PB 5/12 24 7.5YR 8/4 7.5YR 7/ 4 51 7 . 5PB 3/ 10 7.5PB 4/12 25 2.5YR 8/4 2.5YR 7/4 52 SP 2.5 / 4 5P 3/10 26 7.5R 8/4 7 .5R 7/4 53 5RP 2.5/4 5RP 3/ 6 27 2.5R 8/ 4 2 . 5R 7/ 4 54 SR 2.5/4 5R 3/4 ~ach designation indicates hue, value, and chroma in the form H V /C. Hue is divided into 10 groups (red, yellow-red, yellow, green- yellow , green , blue- green, blue, purple-blue, purple, and red-purple); each group is furthe r subdivided by use of numerals (2.5 , 5 , 7.5, and 10 for the ASTP color wheel). Value is specified on a numerical scale from 1 (black) to 10 (white). Chroma is indicated numerically from 0 to 12 (for the ASTP color wheel) . b See fig. 10-2 (a) . cSee fig. 10-2 (b). 10-27 TABLE 10-VII.- MISSION TASK ASSIGNMENTS Revolution Mapping tasks Visual observation tasks Site Crewmember Site Crewmember (a) (a) 15 M1 ACDR 5A, 5B, 5C DMP 17 M2, M3 DMP 12A, 1, 3A, 2A, 4C, 5C CMP 39 M4 DMP lOA, lOB , 10C, 10D, 10E DMP 40 M5 DMP 9A, 9B DMP 42 8A, 3A , 9H, 91, 9J DMP 45 5D, 5A, 5E, 5F , 5C DMP 46 2E, 4D CMP 64 M6 ACDR llC ~ llB , 3A CMP 71 M7 DMP 9C , 9D , 9E, 9F, 9G CMP 72 M8, M9 ACDR b 12, 8A, 9H, b 9I , b 9J DMP 73 3A , 9K , 9L ACDR 74 7B , 7C, 6A, 6B ACDR 78 3C , 4A DMP 79 1IA, llB, 3A DMP 88 8B , 8C, 8D , 8E, 3A , 9K , 9L ACDR 90 5D, 5A, 5E, 5G, 5F, 5C , 6A, 9P DMP 104 7A , 7D, 7E ACDR 106 3B, 2B , 2E, 4D CMP 107 M10 CMP 2C , 2D CMP 108 3C , 4B CMP 123 UD DMP 124 4A, 4C, 4D CMP 134 7F , 7G, 6A , 6B, 9M , 9N , 9P ACDR 135 Mll DMP 3B, 5A , 5G, 5F, 6A, 9L, 90, 9P CMP aACDR , Apollo commander; DMP, docking module pilot ; CMP, command module pilot. b DAC . 10-28 I-' o I t-.:) c.o Sensor type Vinten Vinten Vinten Vinten RC-I0 -.----- - 'j TABLE 10-VIII.- AIRCRAFT SUPPORT SENSOR DATA Lens focal length, Film type Filtration Spectral band, Percent of cm (in.) nm overlap 4.45 (1. 75) Panatomic-X, Schott GG 475 to 575 60 3400 475 and Schott BG 18 4.45 (1. 75) Panatomic-X , Schott OG 580 to 680 60 3400 570 and Schott BG 38 4.45 (1. 75) Infrared Schott RG 690 to 760 60 Aerographic, 645 and 2424 Corning 9830 4.45 (1.75) Aerochrome Wratten 12 510 to 900 60 Infrared , 2443 15.24 (6) Aerial color , 2.2AV 400 to 700- 60 SO- 242 ..... o I W o L ___ ._ Ml M2 M3 Mapping pass Gulf Stream New Zealand Southern California TABLE lO- IX.- PHOTOGRAPHIC MAPPING RESULTS Description Fracture pattern of a micro? crustal plate that includes the Yucatan Peninsula Eddies and currents in the Yucatan Channel Red tide off western coast of Florida Eddies and gyres of Gulf Stream Photography of Alpine Fault Internal waves Plankton b looms Eddies in South Pacific Ocean water color Red tide off coast of California Subsystems of San Andreas Fault Desert colors and processes in the Mohave Desert Remarks Mapping camera photography was canceled on revolution 15/16 because of Flight Plan problems. Alpine Fault photography was not successful because of cloud cover; however, all other objectives were achieved. The ocean part of the mapping strip was partly cloudy; excellent photography was obtained of the land part. _ ___ -.--l ~ o I W ~ M4 M5 M6 Mapping pass Himalaya Mountains Arabian Desert Australia TABLE lO-lX . - Continued Description Shoreline processes at Zambezi Ri ver Delta margin Sediment plumes in Somali Current Ocean currents in Arabian Sea Flood plains of the Indus River Drainage patterns of foothills of Himalayas Photography of snow cover Remarks Excellent photography was acquired over the Indian Ocean and Arabian Sea; however, most of India (and particularly the Himalayas) was completely cloud covered. Afar Triangle Scatte r e d clouds covered the western part of the Afar T riangle, but the weather was clear Structures on border of Red Sea rift from eastern Afar to Qatar and good photog- Dune patterns in Ar- Rub AI- Khali Coastal processes at Doha, Qatar Playas in the Lake Eyre region Dune patterns in Simpson Desert Great Barrier Reef Eddies in the Coral Sea raphy was acquired. . The weather was good all along the revolution 64 ground track , and excellent photographs of Australia and the Coral Sea were obtained. ~ I-' o I Vj ~ --- M7 M8 M9 Mapping pass African drought Falkland Current Sahara TABLE-IO-IX. - Continued Description Guinea Current Lake Chad region, vegetation and land use patterns Desert colors in northeastern Africa Sand dune patterns and their rela? tion to vegetation and wind Nile River Delta Levantine Rift: structures of Golan Heights and southern Turkey Continental-shelf waters Falkland Current and its relation? ship to fisheries Niger River Delta: dune patterns and l'and use of the Inland Delta for comparison with Sky lab data on the Sahel Desert color and relation to age Desert dunes and their relation to topography, moisture, and vegetation Coastal processes at Tripoli Eddies in waters between Tripoli and Sicily Remarks Photography of the Guinea Current was not suc ? cessful because of cloud cover; however, the weather was clear from Lake Chad to the Levantine Rift and excellent photographs were obtained. The spacecraft attitude for this pass was not nominal and resulted in oblique photography with the horizon occupying much of the frames . South of the Niger River Delta, cloud cover ob ? scured much of the terrain, but the weather was clear north of the delta. Photographs of the Sahara are slightly overexposed, but those over the land-water interface at Tripoli are excellent. r .- .--- .---- ~ C> I W W Mapping pass MI0 Northern California Mll New England .~----.------~----.- TABLE 10- IX.- Concluded Description Ocean water color Red tide occurrences Subsystems of San Andreas Fault Metamorphic foothills of Sierra Nevadas Mexican volcanoes Sediment patterns in Gulf of Mexico waters Eddies and gyres in Gulf of Mexico Mississippi River Delta Potomac River pollution Red tide occurrences off coast of Massachu setts and Maine Remarks Photographs of northern California are good , although some frames are slightly over? exposed. Mapping pass photography on revolution 135/136 is out of focus, probably because the 80-mm lens (used for the electrophoresis experiment) was s ubs titute d for the 60- mm lens. ~ I l t-' o I W 01>0 1 2A 2B 2C Target designation New Zealand Southern California Baja California California Current TABLE 10- X . - VISUAL OBSERVATION RESULTS Description Remarks Alpine Fault photographs The Alpine Fault was cloud covered, but visual observations of ocean waters northeast of New Internal waves between North Zealand were recorded. The color wheel was and South Islands used, and the crew reported that the ocean color was close to 47- B. Plankton blooms Pacific water color Current boundaries Cloud cover obscured much of the ocean, but interesting cloud waves were observed in the Red tide off coast lee of the Channel Islands. A color wheel reading of 16-A was given to the Gran Desierto. Gran Desierto color Desert varnished hills Pacific water color Oblique photographs were obtained over the Baja peninsula, but there were no crew commen ts. Bahia Concepcion Fault Internal waves in Gu lf of California Gray rock exposures Pacific water color There was some cloud cover over the ocean, but a color reading of 47- B was t aken for the Faults west of San Andreas coastal waters just offshore from San Francisco. Foothill metamorphic range - -- ---- ~ ---------------- 1 r TABLE lO-X.- Continued Target designation Description Remarks 2D Great Salt Lake Bonneville track Excellent photographs of the Great Salt Lake were acquired. In addition, the crew re- Color boundaries and sediment ported that the Bonneville track could be plumes in lake easily detected. Bingham copper mine Snow cover on the Wasatch Range 2E Guadalaj ara Major fault lines No visual observations were made or photographs taken of the Guadalajara area; however, good Big Bend structures photography was obtained of a part of the Mex- ican volcanic belt southeast of Guadalajara. 3A Cloud features Photographs of convective A number of excellent photographs were obtained clouds including Benard cells, atmospheric bow waves, rotor clouds, and severe thunderstorms. 3B Tropical storms Storm centers Good data were acquired on both developing and dissipating tropical storms. Texture of storms 3C Hawaii Upwellings, bow waves, No photographs were taken of the Hawaiian island wakes islands, but excellent data were obtained of eddies and currents southeast of the islands. Kilauea Volcano 3D Kuroshio Current Ocean current boundary Some photography was acquired in the South China Sea. Plankton blooms 4A Snow cover Snow- peaked mountains Excellent photographs were obtained of glaciers and snow-peaked mountains in both the Cas- Glaciers and firn lines cade and Canadian Rocky Mountains. - t-' o I c..:> 0) 4B 4C 4D 5A 5B 5C 5D Target designation Puget Sound Superior iron Sudbury nickel Gulf of Mexico Gulf Stream Labrador Current Central American structures ~- ---------- TABLE 10- X .- Continued Description Remarks Suspended sediments Valuable photographic and verbal data were ob- tained of sediments and gyres in the Puget Gyres Sound. Glaciers and firn lines Color oxidation zones No photographs were taken but visual observa- tion comments were made on color oxidation zones in the Superior region . Color oxidation zones Photography of the Sudbury area was unsuccess- ful because of cloud cover. Eddies in Yucatan Channel Excellent data were obtained, including photog- raphy of eddies in the Yucatan Channel and Florida Current current boundaries in the Gulf of Mexico. Gulf Loop Current Internal waves in Gulf Qcean current boundary This target was canceled on revolution 15/16 because of Flight Plan problems. Internal waves Confluence with Labrador extension Ocean current boundary The ocean northeast of Newfoundland was cloud covered and no photographs were taken. Confluence with Gulf Stream Bartlett Fault extension Central America was usually cloud covered and visual observations of fault structures Graben valley structures could not be made. ------------------------------------------------- ( f-' o I W -:J 5E 5F 5G 6A 6B 7A 7B 7C 7D Target designation Florida red tide New England red tide Chesapeake Bay Oil slicks London Humboldt Current Na zca Plain Internal waves Peruvian desert TABLE lO-X. - Continued Description Remarks Red tide location The crew reported cloud cover over the Florida peninsula during every visual observation Color and shape of bloom pass. Red tide location Boothbay Harbor in Maine was always cloud covered. but excellent photographs of coastal Color and shape of bloom waters of Massachusetts and Canada were taken. Sediment gyres Valuable photographic and verbal data were ob- tained of sediment gyres and pollution plumes Pollution in Potomac River in the Chesapeake Bay. Oil slick extent No oil slicks were observed in the North Atlan- tic. but some photographs of slicks were Color and location acquired over the Persian Gulf and the Medi- terranean Sea. Sediments and boundaries England was usually cloud covered, but some in English Channel photographs were taken along the coasts of England and France. London Harbor area Ocean current boundary Photography of the Humboldt Current was successful . Gyres in water Nazca Plain markings Some photography was obtained of the Nazca region, but the crew could not definitely con- Peruvian desert landforms firm visual sightings of the Nazca Plain markings. Photographs of internal waves Excellent photographs were taken of internal waves off Thailand and west of Spain. Dune fields Valuable photographic data of dune fields in the Peruvian desert were acquired. Nazca Plain markings ---------- , ---I ,I I ..... <=> I c...:> 00 7E 7F 7G BA BB . BC Target designation Orinoco River Delta Galapagos Islands Caribbean Sea Falkland Current Chilean Andes Dune field "----~---- ~ TABLE lO-X.- Continued Description Remarks Photographs of delta Photographic and verbal data of the Orinoco River Delta included excellent photography of Water color n ear Barbados ocean waters between the delta and Barbados as well as visual observations of the extent of "brown water" outflow from the delta . Upwellings Excellent photography was acquired of the vol - canic calderas on the Galapagos and of the Bow waves complex atmospheric wave patterns surround- ing the islands . Is land wakes Intern al waves Eddies A number of photographs were taken of the Caribbean waters and the islands of Cuba and Gulf Stream Jamaica. Ocean current boundary The spacecraft attitude was not nominal for the revolution 72 pass , and the viewing angle out Plankton blooms window 3 was very oblique. Confluence with Brazil Current I Color oxidation The Chilean Andes were cloud covered and only a few very high peaks were visible. Structures and lineaments Dune field color Excellent photography was obtained of this little- known dune field and of a smaller unknown Dune pattern and orientation field to the east. Relation with topography - '- f-" o I c...:> to 8D 8E 9A 9B 9C 9D 9E Target designation Parana River Circular structures Afar Triangle Arabian Penins ula Guinea Current Desert colors Oweinat Mountain ----- --[ TABLE lO-X.- Continued Description Remarks Photographs of dam sites The weather over Paraguay and Brazil was amazingly clear, and excellent data were acquired of potential dam sites on the Parana and Paraguay Rivers. Additional photographs were taken of the Amazon River. Photographs of two structures Excellent photography of one possible astrobleme was obtained. Ethiopian Plateau scarp The Afar Triangle was mostly cloud covered. The infrared photography is out of focus. Red Sea mountains Structures normal to Red Sea Infrared photography of the Arabian Peninsula is out of focus. Desert color Dune types Coastline of Qatar Ocean current boundary Currents and gyres in the Gulf of Guinea could not be observed because of cloud cover. Gyres in water N'Djamena photographs Excellent photography was obtained of the Lake Chad area and of desert colors and dune pat- Desert colors terns in the Libyan Desert. Dune patterns Photographs of mountain Valuable data were obtained over the Oweinat Mountain, including excellent photography and Structures in mountain verbal observations of s tructural features and color zonations. Color oxidation zones f-' o I >l>o o 9F 9G 9H 91 I 9J 9K '--- Target designation Nile Delta Levantine Rift Niger River Delta Algerian Desert Tripoli Strait of Gibraltar -- - -- - ------- TABLE lO-X .- Continued Description Remarks Observation of pyramids A number of photographs were acquired over the Nile Delta and included excellent near-vertical Photographs of Cairo photography of th e Cairo area. Gulf of Suez structures Arcuate fault photographs Excellent data were ob tained on the arcuate ter- minations of the Levantine Rift. Terminations of faults Dune generations Photography of the Niger River Delta was not successful because of cloud cover. Vegetation patterns Desert colors Good photography was taken of the Algerian Desert; observations of color zones and sand- Dune patterns s torms were also made. Interdune areas Desert and vegetation relationship African coastline Data for this target included good photography of the land- water interface at Tripoli and of Eddies. gyres. current bound- current boundaries in the Mediterranean Sea. aries. internal waves in Mediterranean Sea Coastline at Casablanca Excellent photography of the Strait of Gibraltar was acquired. and the crew was successful in Atlas Mountains observing internal waves and current bound- aries. Good photographic data were also Ocean current boundaries acquired of central and southern Spain. Internal waves --- .~-~- - ----------- t-" o I ~ t-" 9L 9M 9N 90 9P lOA lOB Target designation Alps Danube Delta Anatolian Fault Volcanics Bioluminescence Great Dike Somali Current j TABLE IO-X. - Continued Description Remarks Snow cover Photographs of snow cover on the Alps were not obtained because of cloud cover . Glaciers and firn lines Photographs of delta The crew was successful in photographing the Danube Delta but reported that most of the Sediment plumes in Black Sea area was very hazy. Photographs of fault Good low-Sun-angle photography was acquired of fault zones in Turkey, including excellent Snow cover on mountains data east of Lice (epicenter of the recent earthquake) . Photographs of Vesuvius Excellent infrared photographs were taken of igneous terrain in Italy. Dark-colored volcanic rocks Brightening of tracks or zones The crew was not successful in observing in the Red Sea, Persian Gulf, bioluminescence in the Red Sea and remarked and Arabian Sea that may be that they were still in sung lint . However, due to biolOgical factors that was 2 min before the scheduled observa- (nighttime observation) tion and they were still over the Mediterra - nean Sea. Earlier in the mission, the mis- sion clocks had been updated 2 min, and the crew was probably using the old ground- elapsed time (GET). Color of Great Dike and Photography and visual observations of this tar- surrounding rock get were not successful . Zambezi River Delta Infrared photography of the delta was out of focus, but observations were made of sedi- Coastal sediment plumes ment plumes and gyres along the coast . Current boundaries Internal waves : -- - - --- ---- -- -- -- ~- --- ---- -- ~ o I "'" t-:) lOC lOD lOE I1A llB llC Target designation Arabian Sea Himalaya Mountains Takla Makan Desert Playas Coral Sea Simpson Desert TABLE lO-X. - Continued Description Remarks Ocean current boundaries The crew was successful in observing a current boundary, but farther north, high cirrus clouds obscured much of the Arabian Sea . Photographs of northwestern The Himalayas were cloud covered and photo- India graphs were out of focus . Desert colors The infrared photography of the Takla Makan was out of focus, but observations were made Dune patterns of what was probably a sandstorm over the desert. Lake Eyre deposits Excellent data were acquired of playas in the Lake Eyre region and included an unusual Desert erosion and dune photograph of the normally dry Lake Eyre patterns with much water. Great Dividing Range Coastal sediment plumes Valuable photography was obtained of ocean fea- tures in the Coral Sea, and the crew was very Great Barrier Reef successful in locating and describing eddies. They also observed the Great Barrier Reef and Water eddies remarked that coastal sediments did not extend as far as the reef. Desert colors Excellent photography was obtained that clearly illustrates the characteristic linear dune pat- Dune fields terns and the red color of the Simpson Desert. Dune types -- _____ ---I I t--' o I "'" W 110 12A Target designation ANZUS Eddy (Tasmanian Sea) Icebergs -I TABLE 10- X. - Concluded Description Remarks ANZUS Eddy Most of the area was cloud covered . but the crew did observe several eddies. one of which may have been the ANZUS Eddy . Photographs of bergs No icebergs were observed in the Southern Hemisphere; however. the crew did see sev- Berg rotation eral large bergs in the North Atlantic and attempted to photograph them. Edge of Antarctica / .... fflJ / .... D '--__ -0;.._ ..... Legend: ... ..... Vis ual observations ? __ ? Mapping and visual obse rvations -- Television j . @ .... ... - (a) Western Hemisphere. Figure 10-1. - Maps showing the broad locations of the Earth observation sites. Small circled numbers represent revolution groundtracks for photographic mapping and visual observation tasks; large circled numbers represent the Earth observation sites. 10-44 Legend: .... " .. V' Isual observat' ___ ? Ma . Ions __ PP!ng and visu I . Television a obse rvations (b) Eastern He . mlsphere Figure 10-1 - Concluded ~ ~ \ \ 10- 45 (a) Desert colors. Figure 10- 2. - Color wheel used for assigning desert and ocean colors during the ASTP visual observations. The color chips are from the Munsell color system (see table 10-VI) , and their grouping resulted from testing during flyover exercises. 10-46 (b) Ocean colors. Figure 10-2. - Concluded. 10-47 cr1f ~---, a~ "- / 1 j ~, - ;-.. Cascades Range Engli sh . -), Ch.OO:'# M.d,,,,,,,,,, S" )l snow cove r " a I ..,, / ~ ~ ~""N~[" ',"d " ISRO ~ Southern c a li fo rni~", 1 red,tide / ;tQ Hi malayas'/ .1 !I ~:/" Florida red tide-f---Stralt of .6 Qatar~- ____ 2)' ~ r 0 ,,,,,hi' Co n" , . / ' \ ,';0.., ,I 1 O'b,,'.' " l1f Big Bend, Texas // L \='" -( Western L ? ) . Gulf of Mexico /t1~~te r n 1"- Dese rt of / : t9 <) ~~ I / Car ibbean ('-) Egypt ( ~ b?a 1_ , t- ra In Guatemala ' ~ ") j J'c Sea /' 1\ n \ r -; : ANZUS Eddy ~-{v "'\ I / f\-.---~~ (] f'z 9 New Zealand Id' (South Pacific) o Ai rcraft suppo rt o Oceanography support 6 Ground support 1 1 )j ~ I SRO - I nd ian Space Research Organi zation ( aircraft suppo rt ) Fi gure 10- 3 , - World map illustrating locations of s upport efforts of the ASTP Earth Observations and Photography Experiment . 10-48 I __ J 1 - ----. I 34 30 1'----?, \ \ I I I \ \ \ \ \ \ + Siwa Oasis MED ITERRANEAN SEA + Dakhla Oasis + Kharga Oasis + Ba ris /",/" OW"OO' ",00'.'0 22 L-____ ~============~==~~==~====~==~~~~~~========~--------~~--- ~ ~ ~ ~ Longitude, deg E Figure 10-4, - Sketch map of Egypt showing the extent of photographic coverage (dotted area) by the mapping camera on revolution 71 (solid line) , A support team from the Ain Shams University in Cairo will provide ground-truth data from the Oweinat Mountain area; the Farafra, Baharlya, and Faiyum Oases; and the Abu Rawash region, 10-49 Figure 10- 5. - The southern part of the Levantine Rift, extending from the Dead Sea to the Sea of Galilee, is distinguished by the linearity of the Jordan River Valley (arrow). To the north, a "fan shaped" complex system of arcuate faults characterizes the rift. One prominent fault parallels the Syrian coast and then makes a noticeable bend to the northwest (AST- 9-564). 10-50 - i J LEVANTINE RIFT 71 1. OBTAIN 3 STEREO PHOTOGRAPHS OF THE ARCUATE TERMINATIONS OF THE LEVANTINE RIFT. 2. CAN YOU DISTINGUISH RELATED GROUPS OF FAULTS? 3. WHERE IS THE NORTHERNMOST TERMINATION OF THIS FAULT COMPLEX? REV 71: CM3/SILVER/250/CX12(f8,1/500) 3FR,[RECORD LAST FR NO: PAGE 4J Figure 10-6. - One page from the Earth Observations Book (visual observation target 9G) that was used by the crew to visually study the Levantine Rift area. 10-51 --- - ----------- Figure 10-7. - The deep-brown color of the Orinoco River outflow is caused by both sediments ' and humic compounds. This turbid water was observed by the crew farther north than the island of Barbados (AST-21-1685). l~52 Figure 10- 8. - The Nile Delta is an excellent example of a triangular-shaped arcuate delta. Patterns of surface texture and boundary layers, easily seen in the Sun's reflection, possibly result from a density difference between the freshwater from the Nile and the more saline water of the Mediterranean Sea (AST-9-558) . 10-53 Figure 10-9.- The Kufra Oasis, in the lower half of the photograph, is charac? terized by circular irrigation patterns. To the north, two faint rings (arrows) are possible astroblemes (AST-16-1244). 10-54 -- l r-- ---- I (a) The Atlantic Ocean appears homogeneous with no visible ocean features in this oblique photograph looking toward the Strait of Gibraltar (AST-27-2365). Figure 10-10. - The Strait of Gibraltar . 10-55 (b) The change in Sun angle in this photograph, taken shortly after figure 10-10 (a) , has made a number of features visible. Orbital photography of the oceans has revealed that the occurrence and magnitude of internal waves is greater than expected. The internal waves in this photograph are approximately 50 to 60 kilometers long (AST-27-2367). Figure 10-10. - Concluded. 10-56 _ _ .J Figure 10-11. - In this photograph of the Bay of Fundy, the red water color is probably due to the deposition of red clays by inflowing rivers. There is a fairly heavy sediment load in the bay; high tidal activity maintains water turbulence (AST-1-67) . 10-57 r '--- Figure 10-12. - This vertical photograph was taken with the mapping camera over the Western Desert of Egypt. A sharp color change marks the bound? ary between the younger, yellow sand sea to the north and the older, orange-red desert associated with the Gilf el Kebir region in the lower part of the photograph (AST-16-1247) . 10-58 I I I I I _J Figure 10-13. - The color difference between the dark-red Simpson Desert and the yellow Western Desert of Egypt in figure 10-12 is readily apparent. The radiating linear dunes in this photograph, described by the crew as "hundreds of parallel road tracks," seem to constitute the characteristic dune pattern in this region (AST-16-1133). 10-59 Figure 10-14. - In this excellent photograph of a little-known dune field in Argentina, the transition between the alluvial fan at the base of the moun? tain and the dune field is very sharp. The general dune pattern is cres? centic with a superimposed secondary linear pattern. To the east of the dune field is a smaller field, the existence of which was previously un ? known (AST-27-2340). 10-60 _~ ___ , _ "'----r Figure 10-15 . - This photograph of the July snow cover was taken over the Cascades in the State of Washington. Snowpack distribution is being mapped to estimate the volume of water reaching drainage systems for use in irrigation (AST-19-1540). 10-61 Figure 10-16. - In this photograph of Lake Chad, the number of emergent dunes within the lake attest to the fact that the lake was once considerably larger. However, various factors, such as the influx of sand from the Sahara, have contributed to a significant decrease in its size (AST-9-550). 10-62 Figure 10-17. - This photograph of an unusual cumulonimbus convective system was taken along the western coast of Mexico over the Gulf of California (AST-9-545). 10-63 Figure 10-18. - The unique, wedge-shaped linear features in this photo? graph t aken over the Pacific Ocean west of southern California are signif? icantly larger than contrails. Their mode of formation is not yet under? stood (AST-1-42). 10-64 I I r ac ACDR A-D amu ANZUS ASTP at. % ATS ATSR BTB CF CGE CM CMC CMMY CMP CN COAS Co-I Con A CPM CSM CTA D-A DAC dc D/L DM DMA DMP DNA DTA ECE ECS EMI EPE EU EUV FCS FOV FWHM GBT GEM GET GMT HDC APPENDIX A ABBREVIATIONS AND ACRONYMS alternating current Apollo commander analog to digital atomic mass unit Australia-New Zealand-United States Apollo-Soyuz Test Project atomic percent Applications Technology Satellite Applications Technology Satellite ranging bromthymol blue agar cryogenic freezer Crystal Growth Experiment command module command module computer corn -meal, malt-extract, yeast-extract agar command module pilot cellulose nitrate crew optical alinement sight Co-Investigator Concanavalin A counts per minute command and service module cellulose triacetate digi tal to analog data acquisition camera direct current diameter to length ratio docking module Defense Mapping Agency docking module pilot deoxyribonucleic acid differential thermal analysis electrical checkout equipment environmental control system electromagnetic interference Electrophoresis Experiment electrophoresis unit extreme ultraviolet fetal calf serum field of view full width, half maximum ground-based test Goddard Earth Model ground elapsed time Greenwich mean time Hasselblad data camera A-l HED HeG HGD HRC HVPS HZE ICRP IF IR ISM JSC KSC LaRC LBL LED LeRC LET LFE lidar MEM NOAA NRL OM PBS PGS PHA PI PMN PVA PWM QT RBE RCS RF RPI SAA SAB SAM SAO SAS SCDR SD SEM SF SFE SI SIM SM SRBC SST STDN A-2 high-energy deposition helium glow helium glow detector Hasselblad reflex camera high -voltage power supply high-charge energy International Commission for Radiation Protection intermediate frequency infrared interstellar medium NASA Lyndon B. Johnson Space Center NASA John F. Kennedy Space Center NASA Langley Research Center Lawrence Berkeley Laboratory light-emitting diode NASA Lewis Research Center linear energy transfer Light Flash Experiment laser radar minimum essential medium National Oceanic and Atmospheric Administration Naval Research Laboratory orbital module phosphate-buffered saline preliminary Goddard solution phytohemagglutinin Principal Investigator polymorphonuclear leukocyte polyvinyl alcohol pokeweed mitogen quantum efficiency and transmission relative biological effectiveness reaction control system r adiofreq uency Rensselaer Polytechnic Institute South Atlantic Anomaly Sabouraud's dextrose agar stratospheric aerosol measurement Smithsonian Ast rophysical Observatory small astronomy satellite Soyuz commander standard deviation scanning electron microscope space flight Soyuz flight engineer simulation index scientific instrument module service module sheep red blood cells supersonic transport or satellite-to-satellite tracking . Spaceflight Tracking and Data Network TE TLD TV UK USB UVA VCO VHF VTR WBC wt. % XBT Z ZFF thermoelectric module thermoluminescence dosimeter thermal vacuum or television urokinase unified S-band ultraviolet absorption voltage-controlled oscillator very high frequency video tape recorder white blood cell weight percent expendable bathythermograph atomic number zone-forming fungi A-3 L APPENDIX B UNITS AND UNIT-CONVERSION FACTORS In this appendix are the names, abbreviations, and definitions of Interna? tional System (SI) units used in this report and the numerical factors for convert? ing from conventional units to SI units. Names and Symbols of SI Units Quantity Name of unit Symbol Definition of symbol SI Base Units Length meter m Mass kilogram kg Time second sec Electric current ampere A Thermodynamic temperature kelvin K Luminous intensity candela cd Amount of substance mole mol SI Derived Units Area square meter 2 m Volume cubic meter m3 - 1 Frequency hertz Hz 3 s Mass density (density) kilogram per cubic meter kg/m Speed, velocity meter per second m/sec Angular velocity radian per second rad/sec Acceleration meter per second squared m/sec 2 Angular acceleration radian per second squared rad/sec 2 Force newton N kg 0 m/sec2 Pressure (mechanical stress) pascal Pa N/m 2 Kinematic viscosity square meter per second m2/sec Dynamic viscosity newton-second per square meter N? sec/m 2 Work, energy, quantity of heat joule J Nom Power watt W J/sec Quantity of electricity coulomb C A 0 sec Potential difference , electromotive force volt V W/A Electric field strength volt per meter Vi m Electric resistance ohm n VIA Capacitance farad F A 0 sec/V Magnetic flux weber Wb V 0 sec Inductance henry H V 0 sec/A Magnetic flux density tesla T Wb/m 2 Magnetic field strength ampere per meter Aim Magnetomotive force ampere A Luminous flux lumen 1m 2 cd 0 sr Luminance candela per square meter cd/m 2 Illuminance lux Ix Im/m Wave number 1 per meter m -1 Entropy joule per kelvin J/K Specific heat capac,:!: joule per kilogram kelvin J/(kg 0 K) Thermal conductivi watt per meter kelvin W/(m 0 K) Radiant intenSity watt per steradian W/sr Activity (of a radioactive source) 1 per second s-l SI Supplementary Units Plane angle radian rad 1 Solid angle steradian sr B-1 I , I --- Unit Prefixes Prefix Abbreviation Factor by which unit is multiplied giga G 109 mega M 106 kilo k 103 centi c 10-2 milli m 10- 3 micro ~ 10- 6 nano n 10-9 pi co p 10-12 --- - Unit Conversion Factors The following table expresses the definitions of units of measure used in the Apollo-Soyuz Test Pr oject Preliminary Science Report as exact numerical multiples of coherent SI units and provides multiplying factors for converting to SI units. The first two digits of each numerical entry represent a power of 10. An asterisk follows each number which expresses an exact definition. To convert from - To - Multiply by - angstrom meter -10 1.00* atmosphere newton/meter 2 +05 1. 013 25* Celsius (temperature) kelvin tK = tc + 273.15 foot meter -01 3.048* gram kilogram -03 1. 00* inch meter -02 2.54* pound mass (lbm avoir - kilogram -01 4.535 923 7* dupois) torr (0 0 C) newton / meter 2 +02 1. 333 22 B-2 Experiment Microbial Exchange (AR-002) Stratospheric Aerosol Measurement (MA- 007) Multipurpose Electric Furnace (MA- OIO) Electrophoresis Tech ? nology (MA-Oll) Electrophoresis (MA- 014) Crystal Growth (MA - 028) Soft X- ray Observation (MA- 048) Ultraviolet Absorption (MA-059) Extreme Ultraviolet Survey (MA-083) APPENDIX C HARDWARE VENDORS Equipment supplied Experiment hardware Experiment hardware Experiment hardware Experiment hardware Thermoelectric assembly Column assemblies Experiment hardware Experiment hardware Camera equipment and accessories Experiment and ground-support equipment (GSE) Data subsystem Experiment. optical system. and GSE Retroreflector optics (built and tested) Ultraviolet (UV) light source (built) UV light assembly (design and assembly) Retroreflector mount. UV and incandescent light sources. and GSE Experiment and GSE Telescope UV filters C-l Vendor General Electric Company Houston . Tex. University of Wyoming Laramie. Wyo. Westinghouse Astronuclear Pittsburgh. Pa. Teledyne Brown Engineering Huntsville. Ala. Ohio Semitronics Columbus. Ohio NASA George C . Marshall Space Flight Center Huntsville. Ala . Messerschmitt-Bolkow- Blohm Ottobeuren. West Germany Rockwell International Science Center Thousand Oaks, Calif. NASA Lyndon B. Johnson Space Center Houston. Tex. Ball Brothers Research Corporation Boulder. Colo. New Mexico State University Las Cruces . N. Mex. Johns Hopkins University Applied Physics Laboratory Laur~l, Md. Precision Lapping and Optical Company Valley Stream. N. Y . Intraspace International Inc . Toronto. Ontario. Canada Lockheed Electronics Houston . Tex. NASA Lyndon B. Johnson Space Center Houston , Tex. Ball Brothers Research Corporation Boulder. Colo. Applied Optics Center Burlington. Mass. Luxel Corporation Santa Barbara. Calif. C-2 Experiment Interstellar Helium Glow (MA-088) Doppler Tracking (MA-089) Light Flash (MA-106) Biostack (MA -107) Earth Observations and Photography (MA-136) Crystal Activation (MA-151) Science Demonstrations ------------??--------------------1 Equipment supplied Experiment and GSE Helium pressure vessel Helium system valves UV filters Transmitter , receiver, and GSE Ultrastable oscillators for trans ? mitters and receivers, crystal filters for transmitters Transmitter battery development Receiving antenna (design and development) Data recording system Experiment hardware Experiment hardware 70-mm cameras, magazines, lenses, and accessories for photography 20X binoculars for visual observations Standard color chips for visual color comparisons Zoom telescope for visual observations Variable intervalometer for sequencing photography; 16- mm camera equipment for complementary strip mapping Experiment hardware Experiment hardware Vendor Ball Brothers Research Corporation Boulder, Colo. Supplied by NASA Sterer Valves Engineering & Manufacturing Los Angeles, Calif. Luxel Corporation Santa Barbara, Calif. Raytheon Company Equipment Division Sudbury, Mass. Frequency Electronics, Inc. New Hyde Park, N . Y . Eagle Picher Joplin , Mo. Ball Brothers Research Corporation Boulder, Colo. NASA Lyndon B. Johnson Space Center Houston, Tex. Lawrence Livermore Laboratory UniVersity of California Berkeley, Calif. Messerschmitt-Bolkow-Blohm Ottobeuren, West Germany Victor Hasselblad, Aktiebolag Sweden Tasco Sales, Inc. Miami, Fla . Munsell Color Company Macbeth Division Baltimore, Md. Bushnell Optical Corporation Pasadena , Calif. Perkin Elmer Corporation Aerospace Division Pomona, Calif. NASA Goddard Space Flight Center Greenbelt, Md. NASA George C. Marshall Space Flight Center Huntsville, Ala. -- --- -- - ~- -- --- _. - ----- --- f' APPENDIX D POINTS OF CONTACT Experiment no. I Engineering development manager Science coordinator AR-002 MA-007 MA-028 MA-031 MA-032 MA-048 MA-059 MA-083 MA-088 MA-089 MA-l06 MA-l07 MA-128 MA-147 MA-148 MA-151 MA-161 MA-Ol0 MA-Oll MA-014 MA-041 MA?044 MA-060 MA-070 MA-085 MA-131 MA-150 NASA Lyndon B . Johnson Space Center G. R. Taylor, DD7 J. R. Bates , TN3 C. J. LeBlanc, ED6 J. R. Bates , TN3 S. L. Kimzey, DB 7 S. L. Kimzey, DB 7 E. L. Weeks, ED6 S. N. Hardee, TN3 L. W. McFaden, ED6 S. R. Mansur, TN3 J. M. Sanders, ED6 R. R. Baldwin, TN3 J. M. Sanders, ED6 R. R. Baldwin , TN3 A. R. Cunningham , EE6, P. E. Lafferty, TN3 and J. S. Kelley, EE3 J. D. Lem, DE4 R. A. Hoffman , DD6 H. S. Anton a J. V. Bailey , DD6 P. E. Lafferty , TN3 G. R. Taylor, DD7 R. T. Giuli, TN3 S. R. Mansur, TN3 R. A. Hoffman , DD6 NASA George C. Marshall Space Flight Center A. Boese, EL55 R. E. Allen , EH35 R. S. Snyder, EH12 A. Boese, EL55 A. Boese, EL55 A. Boese, EL55 A. Boese, EL55 A. Boese, EL55 A. Boese, EL55 A. Boese, EL55 A. Boese , EL55 R. E. Allen , EH35 R. S. Snyder , EH12 R. C. Ruff , ES12 L. L. Lacy, ES 24 C. F. Schafer, ES12 C. S. Griner, EH12 M. C. Davidson , ES12 M. H. Johnston , EH12 A. Boese, EL55 ~inistry of Research and .Technology, Federal Republic of Germany , Gesellschaft Fuer Weltraumforschung, 505 Porz-Wahn, Linder Hoehe, West Germany. n U 5 GOVERN M ENT PRINTIN G OFf i CE 1976-0-675-606 D-l