Apollo 11 missing tapes

Last updated

The original slow-scan television signal from the Apollo TV camera, photographed at Honeysuckle Creek on July 21, 1969 Apollo11TV5.jpg
The original slow-scan television signal from the Apollo TV camera, photographed at Honeysuckle Creek on July 21, 1969

The Apollo 11 missing tapes were those that were recorded from Apollo 11's slow-scan television (SSTV) telecast in its raw format on telemetry data tape at the time of the first Moon landing in 1969 and subsequently lost.

Contents

The data tapes were used to record all transmitted data (video as well as telemetry) for backup.

To broadcast the SSTV transmission on standard television, NASA ground receiving stations performed real-time scan conversion to the NTSC television format. The moonwalk's converted video signal was broadcast live around the world on July 21, 1969 (2:56 UTC). At the time, the NTSC broadcast was recorded on many videotapes and kinescope films. Many of these low-quality recordings remain intact. As the real-time broadcast worked and was widely recorded, preservation of the backup video was not deemed a priority in the years immediately following the mission. [1] In the early 1980s, NASA's Landsat program was facing a severe data tape shortage and it is likely the tapes were erased and reused at this time. [2]

A team of retired NASA employees and contractors tried to find the tapes in the early 2000s but was unable to do so. The search was sparked when several still photographs appeared in the late 1990s that showed the visually superior raw SSTV transmission on ground-station monitors. The research team conducted a multi-year investigation in the hopes of finding the most pristine and detailed video images of the moonwalk. If copies of the original SSTV format tapes were to be found, more modern digital technology could make a higher-quality conversion, yielding better images than those originally seen. The researchers concluded that the tapes containing the raw unprocessed Apollo 11 SSTV signal were erased and reused by NASA in the early 1980s, following standard procedure at the time. [1] [3] [4]

Although the researchers never found the telemetry tapes, they did discover the best visual quality NTSC videotapes as well as Super 8 movie film taken of a video monitor in Australia, showing the SSTV transmission before it was converted. These visual elements were processed in 2009, as part of a NASA-approved restoration project of the first moonwalk. At a 2009 news conference in Washington, D.C., the research team released its findings regarding the tapes' disappearance. They also partially released newly enhanced footage obtained during the search. Lowry Digital completed the full moonwalk restoration project in late 2009.

Background

The television camera, as it was positioned on the Apollo Lunar Module Eagle at the start of the first lunar EVA (Extravehicular Activity) Ap11-S69-31575HR.jpg
The television camera, as it was positioned on the Apollo Lunar Module Eagle at the start of the first lunar EVA (Extravehicular Activity)

Apollo 11 was the spaceflight that landed the first two people on the Moon. Neil Armstrong became the first person to step onto the lunar surface on July 21, 1969, at 02:56 UTC; Buzz Aldrin joined him 19 minutes later. Only limited radio bandwidth was available to transmit the video signal from the lunar landings, which needed to be multiplexed with other communication and telemetry channels beamed from the Lunar Module Eagle, back to Earth. [5] Therefore, Apollo 11's moonwalk video was transmitted from the Apollo TV camera in a monochrome SSTV format at 10 frames per second (fps) with 320 lines of resolution, progressively scanned. [6] These SSTV signals were received by radio telescopes at Parkes Observatory in Australia, the Goldstone tracking station in California, and Honeysuckle Creek tracking station, also in Australia. [7] The camera's video format was incompatible with existing NTSC, PAL, and SECAM broadcast television standards. It needed to be converted before it could be shown on broadcast television networks. This live conversion was crude, essentially using a video camera pointing at a high-quality 10-inch (25 cm) TV monitor.

Video signal processing

Since the camera's scan rate was much lower than the approximately 30 fps for NTSC video, [Note 1] the television standard used in North America at the time, a real-time scan conversion was needed to be able to show its images on a regular TV set. NASA selected a scan converter manufactured by RCA to convert the black-and-white SSTV signals from the Apollo 7, 8, 9 and 11 missions. [8]

When the Apollo TV camera radioed its images, the ground stations received its raw unconverted SSTV signal and split it into two branches. One signal branch was sent unprocessed to a 14-track analog data tape recorder, where it was recorded onto 14-inch (36 cm) diameter reels of one-inch-wide (25 mm) analog magnetic data tapes at 120 inches (3.0 m) per second. [9] The other raw SSTV signal branch was sent to the RCA scan converter, where it was processed into an NTSC broadcast television signal. [9]

The RCA scan converter operated on an optical conversion principle. [10] The conversion process started when the signal was sent to a high-quality 10-inch (25 cm) video monitor, where a conventional RCA TK-22 television camera—using the NTSC broadcast standard of 525 scanned lines interlaced at 30 fps—merely re-photographed its screen. The monitor had persistent phosphors that acted as a primitive framebuffer. [11] An analog disk recorder, based on the Ampex HS-100 model, was used to record the first field from the camera. [11] It then fed that field, and an appropriately time-delayed copy of the first field, to the NTSC Field Interlace Switch (encoder). The combined original and copied fields created the first full 525-line interlaced frame and the signal was then sent to Houston. [11] The disk recorder repeated this sequence five more times, until the camera imaged the next SSTV frame. [11] The converter then repeated the whole process with each new frame downloaded from space in real time. [10] In this way, the RCA converter produced the extra 20 frames per second needed to produce flicker-free images to the world's television broadcasters. [8]

Apollo11A.jpg
Apollo11b.jpg
Photograph of the original SSTV signal of Aldrin and Armstrong at the foot of Eagle (left)—its conversion for broadcast (right) significantly degraded its image quality

This live conversion was crude compared to early-21st-century electronic digital conversion techniques. Image degradation was unavoidable with this system as the monitor and camera's optical limitations significantly lowered the original SSTV signal's contrast, brightness and resolution. If the scan converter's settings were incorrectly set, as they were at the Goldstone station during the first few minutes of Apollo 11's moonwalk, the negative impact on the image could be very obvious. [12] When Armstrong first came down the Lunar Module's ladder, he was barely visible because the contrast and the vertical phase were not set correctly by the scan converter operator. [12] The video seen on home television sets was further degraded by the very long and noisy analog transmission path. [13] The converted signal was sent by satellite from the three receiving ground stations to Houston. Then the network pool feed was sent by microwave relay to New York, where it was broadcast live to the United States and the world. [14] Because all of these links were analog, each one added additional noise and distortion to the signal. [14]

NTSC broadcast tapes

This low-quality optical conversion of the Apollo 11 moonwalk video images—made with a TV camera taking pictures of a video monitor—is what was widely recorded in real-time onto kinescope film and NTSC broadcast-quality two-inch quadruplex videotape. Recordings of this conversion were not lost and have long been available to the public (along with much higher-quality video from later Apollo missions). If the one-inch (25 mm) data tapes, containing the raw unprocessed Apollo 11 SSTV signals, were to be found, modern digital technology would allow for significantly better conversion and processing. [1] [15] The quality would be similar to that viewed by a few technicians and others at SSTV-receiving ground stations before the video was converted to NTSC. [16]

In 2005, an amateur Super 8 movie with about 15 minutes of Apollo 11 images was rediscovered. The footage had been taken by Ed von Renouard at Honeysuckle Creek tracking station during or immediately after the Apollo 11 moonwalk. The images show mainly the scan converted monitor and briefly the slow-scan monitor. [17] This is some of the best quality recording of brief segments of the Apollo 11 moonwalk available. [15] The images are available on DVD. [18]

Search for the missing tapes

News that these analog data tapes were missing emerged on August 5, 2006, when the print and online versions of The Sydney Morning Herald published a story with the title One giant blunder for mankind: how NASA lost moon pictures. [19] The missing tapes were among over 700 boxes of magnetic data tapes recorded throughout the Apollo program that have not been found. [20] On August 16, 2006 NASA announced its official search, saying, "The original tapes may be at the Goddard Space Flight Center ... or at another location within the NASA archiving system" and "NASA engineers are hopeful that when the tapes are found they can use today's digital technology to provide a version of the moonwalk that is much better quality than what we have today." [21] NASA also had ongoing research reasons for finding these higher-resolution tapes, as the Constellation program shared some similar tasks with the original Apollo program. [22]

The Goddard Center's Data Evaluation Laboratory has the only known surviving piece of equipment that can read the missing tapes and was set to be closed in October 2006, causing some fear that, even if the tapes were later found, there would be no ready way to read and copy them. [23] However, equipment that could read the tapes was maintained. [1]

On November 1, 2006, Cosmos magazine reported that some NASA telemetry tapes from the Apollo project era had been found in a small marine science laboratory in the main physics building at Curtin University in Perth, Western Australia. One of these tapes was sent to NASA for analysis. [24] It carried no video but did show that if any of the tapes are ever found, data could likely be read from them. [25]

NASA news conference

NASA held a news conference at the Newseum, in Washington, D.C. regarding the missing tapes on July 16, 2009—the 40th anniversary of Apollo 11's launch from Cape Kennedy. [3] The multinational research team looking into the missing tapes—mostly retired engineers who had worked on the original broadcast in 1969—was represented at the event by Richard Nafzger from the Goddard Space Flight Center and Stanley Lebar, the former lead engineer at Westinghouse who developed the Apollo Lunar Camera and the Apollo Color Camera. [13] They concluded that the data tapes—with the SSTV signal—were shipped from Australia to Goddard and then erased and reused by NASA in the early 1980s in order to be reused in the Landsat program, which was facing a severe data tape shortage at that time. [2] [3]

Australian backup tapes were also erased after Goddard received the reels, [1] following the procedures established by NASA. [4] The SSTV signal was recorded on telemetry data tapes mostly as a backup in case the real-time conversion and broadcast around the world failed. Since the real-time broadcast conversion worked, and was widely recorded on both videotape and film, the backup video was not deemed important at the time. [1]

There was also documentation that the Apollo 11 moonwalk SSTV was recorded at the Parkes, Australia facility on modified Ampex two-inch helical scan VTRs. [1] [26] The VTRs were modified by Johns Hopkins University's Applied Physics Labs to record 320-line slow-scan video directly to the videotape without converting it. [1] [2] It was confirmed that these tapes were shipped to Johns Hopkins University, but they could not be found by the search team. [1]

Nafzger stated that the team did find several post-conversion copies of the broadcast that were of higher quality than what had been previously seen by the public. [3] Their findings included a videotape recorded in Sydney after the conversion but before the satellite transmission around the world, videotape from CBS News archives (direct from NASA, without commentary) and kinescopes at Johnson Space Center. [3] At the news conference, it was mentioned that Lowry Digital would complete enhancing and restoring the tapes. [3] Mike Inchalik, president of Lowry Digital, mentioned that his company would only restore the video and would not remove defects (such as reflections that looked like flag poles). [1] A few short clips were shown at the news conference, showing their improved quality. [3] NASA released some partially restored samples on its website after the news conference. [27] The full restoration of the footage, about three hours long, was completed in December 2009.[ citation needed ]

Some other footage from Australian ground-station feeds showing SSTV video of Armstrong's descent and first steps surfaced through John Sarkissian's efforts. [28] Highlights of this fully enhanced video were shown to the public for the first time at the Australian Geographic Society Awards on October 6, 2010, where Buzz Aldrin was the guest of honor. [29] [30]

Subsquent events

On July 6, 2019, Sotheby's announced that they would have available for sale, on July 20, three 2-inch (50 mm) video tape reels—out of a total of 1,150 reels—bought at a government surplus auction in 1976, at a price of $218 US dollars. The three reels were said to be first-generation recordings of the Apollo 11 EVA video, [31] but were not the missing 1-inch (25 mm) telemetry data tapes. [32] The tapes had been purchased in 1976 at a General Services Administration auction, by Gary George, then an engineering student at Lamar University. George had learned about these "government surplus" auctions while an intern at the Johnson Space Center. [33] On July 20, 2019, the fiftieth anniversary of the first moonwalk, the three tapes were sold to an undisclosed buyer for 1.82 million USD, according to Sotheby's. [34] [35] Although Sotheby's described these tapes as "the best surviving NASA videotape recordings of the historic Apollo 11 Moon Landing" and "the earliest, sharpest and most accurate surviving video images of man's first steps on the moon", [36] a statement from NASA said these tapes "contain no material that hasn't been preserved at NASA". [33]

See also

Notes

  1. For the purposes of clarity and simplicity in this article, 60 fields and 30 frames per second are used. NTSC actually runs at 60/1.001 ≅ 59.94 fields per second, and 30/1.001 ≅ 29.97 frames per second. Two interlaced fields create one complete video frame.

Related Research Articles

<span class="mw-page-title-main">Video</span> Electronic moving image

Video is an electronic medium for the recording, copying, playback, broadcasting, and display of moving visual media. Video was first developed for mechanical television systems, which were quickly replaced by cathode-ray tube (CRT) systems, which, in turn, were replaced by flat-panel displays of several types.

<span class="mw-page-title-main">Slow-scan television</span> Image transmission over radio

Slow-scan television (SSTV) is a picture transmission method, used mainly by amateur radio operators, to transmit and receive static pictures via radio in monochrome or color.

<span class="mw-page-title-main">Surveyor 7</span> American lunar lander

Surveyor 7 was sent to the Moon in 1968 on a scientific and photographic mission as the seventh and last lunar lander of the American uncrewed Surveyor program. With two previous unsuccessful missions in the Surveyor series, and with Surveyor 7's landing success, Surveyor 7 became the fifth and final spacecraft in the series to achieve a lunar soft landing. A total of 21,091 pictures were transmitted from Surveyor 7 back to Earth.

<span class="mw-page-title-main">Surveyor 3</span> American lunar lander

Surveyor 3 is the third lander of the American uncrewed Surveyor program sent to explore the surface of the Moon in 1967 and the second to successfully land. It was the first mission to carry a surface-soil sampling-scoop.

<span class="mw-page-title-main">Moon landing conspiracy theories</span> Claims that the Apollo Moon landings were faked

Moon landing conspiracy theories claim that some or all elements of the Apollo program and the associated Moon landings were hoaxes staged by NASA, possibly with the aid of other organizations. The most notable claim of these conspiracy theories is that the six crewed landings (1969–1972) were faked and that twelve Apollo astronauts did not actually land on the Moon. Various groups and individuals have made claims since the mid-1970s that NASA and others knowingly misled the public into believing the landings happened, by manufacturing, tampering with, or destroying evidence including photos, telemetry tapes, radio and TV transmissions, and Moon rock samples.

<span class="mw-page-title-main">Surveyor 1</span> Lunar lander spacecraft

Surveyor 1 was the first lunar soft-lander in the uncrewed Surveyor program of the National Aeronautics and Space Administration. This lunar soft-lander gathered data about the lunar surface that would be needed for the crewed Apollo Moon landings that began in 1969. The successful soft landing of Surveyor 1 on the Ocean of Storms was the first by an American space probe on any extraterrestrial body, occurring on the first attempt and just four months after the first soft Moon landing by the Soviet Union's Luna 9 probe.

<span class="mw-page-title-main">Lunar Orbiter program</span> Series of five uncrewed lunar orbiter missions

The Lunar Orbiter program was a series of five uncrewed lunar orbiter missions launched by the United States in 1966 and 1967. Intended to help select Apollo landing sites by mapping the Moon's surface, they provided the first photographs from lunar orbit and photographed both the Moon and Earth.

<span class="mw-page-title-main">Surveyor 5</span>

Surveyor 5 is the fifth lunar lander of the American uncrewed Surveyor program sent to explore the surface of the Moon. Surveyor 5 landed on Mare Tranquillitatis in 1967. A total of 19,118 images were transmitted to Earth.

<span class="mw-page-title-main">Ranger 6</span> Failed NASA lunar impactor (1964)

Ranger 6 was a lunar probe in the NASA Ranger program, a series of robotic spacecraft of the early and mid-1960s to obtain close-up images of the Moon's surface. It was launched on January 30, 1964 and was designed to transmit high-resolution photographs of the lunar terrain during the final minutes of flight until impacting the surface. The spacecraft carried six television vidicon cameras—two wide-angle and four narrow-angle —to accomplish these objectives. The cameras were arranged in two separate chains, or channels, each self-contained with separate power supplies, timers, and transmitters so as to afford the greatest reliability and probability of obtaining high-quality television pictures. No other experiments were carried on the spacecraft. Due to a failure of the camera system, no images were returned.

<span class="mw-page-title-main">Ranger 8</span> NASA spacecraft to explore the Moon, 1965

Ranger 8 was a lunar probe in the Ranger program, a robotic spacecraft series launched by NASA in the early-to-mid-1960s to obtain the first close-up images of the Moon's surface. These pictures helped select landing sites for Apollo missions and were used for scientific study. During its 1965 mission, Ranger 8 transmitted 7,137 lunar surface photographs before it crashed into the Moon as planned. This was the second successful mission in the Ranger series, following Ranger 7. Ranger 8's design and purpose were very similar to those of Ranger 7. It had six television vidicon cameras: two full-scan and four partial-scan. Its sole purpose was to document the Moon's surface.

<span class="mw-page-title-main">Honeysuckle Creek Tracking Station</span> Former NASA earth station in Australia

The Honeysuckle Creek Tracking Station was a NASA Earth station in Australia near Canberra. It was instrumental to the Apollo program. The station was opened in 1967 and closed in 1981.

<span class="mw-page-title-main">Apollo TV camera</span> Outerspace broadcasting device

The Apollo program used several television cameras in its space missions in the late 1960s and 1970s; some of these Apollo TV cameras were also used on the later Skylab and Apollo–Soyuz Test Project missions. These cameras varied in design, with image quality improving significantly with each successive model. Two companies made these various camera systems: RCA and Westinghouse. Originally, these slow-scan television (SSTV) cameras, running at 10 frames per second (fps), produced only black-and-white pictures and first flew on the Apollo 7 mission in October 1968. A color camera – using a field-sequential color system – flew on the Apollo 10 mission in May 1969, and every mission after that. The color camera ran at the North American standard 30 fps. The cameras all used image pickup tubes that were initially fragile, as one was irreparably damaged during the live broadcast of the Apollo 12 mission's first moonwalk. Starting with the Apollo 15 mission, a more robust, damage-resistant camera was used on the lunar surface. All of these cameras required signal processing back on Earth to make the frame rate and color encoding compatible with analog broadcast television standards.

<span class="mw-page-title-main">Third-party evidence for Apollo Moon landings</span> Independent confirmations of Apollo Moon landings

Third-party evidence for Apollo Moon landings is evidence, or analysis of evidence, about the Moon landings that does not come from either NASA or the U.S. government, or the Apollo Moon landing hoax theorists. This evidence provides independent confirmation of NASA's account of the six Apollo program Moon missions flown between 1969 and 1972.

Television standards conversion is the process of changing a television transmission or recording from one video system to another. Converting video between different numbers of lines, frame rates, and color models in video pictures is a complex technical problem. However, the international exchange of television programming makes standards conversion necessary so that video may be viewed in another nation with a differing standard. Typically video is fed into video standards converter which produces a copy according to a different video standard. One of the most common conversions is between the NTSC and PAL standards.

A field-sequential color system (FSC) is a color television system in which the primary color information is transmitted in successive images and which relies on the human vision system to fuse the successive images into a color picture. One field-sequential system was developed in 1940 by Peter Goldmark for CBS, which was its sole user in commercial broadcasting. The Federal Communications Commission adopted it on October 11, 1950, as the standard for color television in the United States. Its regular broadcast debut was on June 25, 1951. However, a few months later, CBS ended color broadcasting on October 20, 1951. In March 1953, CBS withdrawn its color system as a standard, creating an opening for all-electronic color systems from other manufacturers.

<span class="mw-page-title-main">British television Apollo 11 coverage</span> 1969 British TV series or programme

British television coverage of the Apollo 11 mission, humanity's first to land on the Moon, lasted from 16 to 24 July 1969. All three UK television channels, BBC1, BBC2 and ITV, provided extensive coverage. Most of the footage covering the event from a British perspective has now been wiped or lost.

<i>Moonwalk One</i> American film

Moonwalk One is a 1971 feature-length documentary film about the flight of Apollo 11, which landed the first humans on the Moon. Besides portraying the massive technological achievement of that event, the film places it in some historical context and tries to capture the mood and the feel of the people on Earth when man first walked on another world.

From 1963 to 1970, Ampex manufactured several models of VTR 2-inch helical VTRs, capable of recording and playing back analog black and white video. Recording employed non-segmented helical scanning, with one wrap of the tape around the video head drum being a little more than 180 degrees, using two video heads. One video drum rotation time was two fields of video. The units had two audio tracks recorded on the top edge of the tape, with a control track recorded on the tape's bottom edge. The 2-inch-wide video tape used was one mil thick. The VTRs were mostly used by industrial companies, educational institutions, and a few for in-flight entertainment.

UPI Newstime was a cable television network founded by United Press International in 1978, and premiered on July 3 of that year. UPI Newstime was the second 24-hour all-news television network in the US for cable TV, following AP Newscable for 13 years and predating CNN by 2 years. UPI Newstime was unique in how it distributed its programming to local cable TV (CATV) headends via satellite, using a form of slow-scan television, or SSTV technology. Using SSTV reduced satellite transmission costs for UPI and was suitable at the time for the programming produced by UPI for the channel, which mainly relied on still slides and wirephotos acquired by UPI's own newsgathering operations.

<span class="mw-page-title-main">Stanley Lebar</span> American engineer

Stanley L. Lebar was an American engineer who constructed the television cameras used during the Apollo program.

References

  1. 1 2 3 4 5 6 7 8 9 10 O'Neil (2009c).
  2. 1 2 3 Nafzger (2009), p. 13.
  3. 1 2 3 4 5 6 7 Perlman (2009).
  4. 1 2 Sarkissian (2006), p. 14.
  5. Coan (1973), pp. 1–2.
  6. Lebar & Hoffman (1967), p. 3.
  7. MacKellar (2005), p. 2.
  8. 1 2 Steven-Boniecki (2010), p. 129.
  9. 1 2 Sarkissian (2006), p. 8.
  10. 1 2 Sarkissian (2006), p. 6.
  11. 1 2 3 4 Wood (2005), pp. 5–6.
  12. 1 2 Wood (2005), pp. 22–24.
  13. 1 2 Von Baldegg (2012).
  14. 1 2 Steven-Boniecki (2010), p. 130.
  15. 1 2 MacKellar (2009).
  16. MacKellar (2005).
  17. MacKellar (2008).
  18. MacKellar (2006).
  19. Macey (2006a).
  20. Sarkissian (2006), pp. 11–12.
  21. Macey (2006b).
  22. Wheeler (2006).
  23. Hansen (2006).
  24. Amalfi (2006).
  25. Nafzger (2009), p. 6.
  26. Nafzger (2009), p. 14.
  27. Jacobs & Hess (2009).
  28. SPACE.com Staff (2010).
  29. Barry (2010).
  30. AG Staff (2010).
  31. "Last remaining moon landing video tapes bought by NASA intern for $218 could sell for millions" . The Independent. July 15, 2019. Archived from the original on May 7, 2022.
  32. Lebar, Scott. "Moon tapes auction is expected to fetch big bucks. NASA clarifies what they are". The Sacramento Bee. Retrieved July 16, 2019.
  33. 1 2 Ed Komenda (July 23, 2019). "Las Vegas man almost tossed the Apollo 11 moonwalk tapes he sold for $1.8 million". Reno Gazette-Journal. Retrieved February 18, 2020.
  34. Theresa Waldrop (July 23, 2019). "3 original NASA moon landing videos sell for $1.82 million at auction". CNN. Retrieved February 18, 2020.
  35. Devin Coldewey (July 22, 2019). "Original Apollo 11 landing videotapes sell for $1.8M". TechCrunch. Retrieved February 18, 2020.
  36. Halina Loft (June 28, 2019). "One Small Step, One Rare Recording: See the Moon Landing Like Never Before" (Press release). Sotheby's. Retrieved February 18, 2020.

Sources

Further reading

Restored post-conversion video