# Pioneer 11

Mission type An artist's impression of a Pioneer spacecraft on its way to interstellar space. Planetary and heliosphere exploration NASA / ARC 1973-019A 6421 Pioneer Project website(archived) NASA Archive page 22 years, 5 months, 25 days TRW 259 kilograms (571 lb) 155 watts (at launch) April 6, 1973, 02:11:00 (1973-04-06UTC02:11Z) UTC Cape Canaveral LC-36B September 30, 1995 (1995-10-01) December 3, 1974 43,000 kilometers (27,000 miles) September 1, 1979 21,000 kilometers (13,000 miles)

Pioneer 11 (also known as Pioneer G) is a 259-kilogram (571 lb) robotic space probe launched by NASA on April 6, 1973 to study the asteroid belt, the environment around Jupiter and Saturn, solar wind and cosmic rays.[1] It was the first probe to encounter Saturn and the second to fly through the asteroid belt and by Jupiter. Thereafter, Pioneer 11 became the second of five artificial objects to achieve the escape velocity that will allow them to leave the Solar System. Due to power constraints and the vast distance to the probe, the last routine contact with the spacecraft was on September 30, 1995, and the last good engineering data was received on November 24, 1995.[2][3]

### Mission background

#### History

Approved in February 1969, Pioneer 11 and its twin probe, Pioneer 10, were the first to be designed for exploring the outer Solar System. Yielding to multiple proposals throughout the 1960s, early mission objectives were defined as:

• Explore the interplanetary medium beyond the orbit of Mars
• Investigate the nature of the asteroid belt from the scientific standpoint and assess the belt's possible hazard to missions to the outer planets.
• Explore the environment of Jupiter.

Subsequent planning for an encounter with Saturn added many more goals:

• Map the magnetic field of Saturn and determine its intensity, direction, and structure.
• Determine how many electrons and protons of various energies are distributed along the trajectory of the spacecraft through the Saturn system.
• Map the interaction of the Saturn system with the solar wind.
• Measure the temperature of Saturn's atmosphere and that of Titan, the largest satellite of Saturn.
• Determine the structure of the upper atmosphere of Saturn where molecules are expected to be electrically charged and form an ionosphere.
• Map the thermal structure of Saturn's atmosphere by infrared observations coupled with radio occultation data.
• Obtain spin-scan images of the Saturnian system in two colors during the encounter sequence and polarimetry measurements of the planet.
• Probe the ring system and the atmosphere of Saturn with S-band radio occultation.
• Determine more precisely the masses of Saturn and its larger satellites by accurate observations of the effects of their gravitational fields on the motion of the spacecraft.
• As a precursor to the Mariner Jupiter/Saturn mission, verify the environment of the ring plane to find out where it may be safely crossed by the Mariner spacecraft without serious damage.[4]

Pioneer 11 was built by TRW and managed as part of the Pioneer program by NASA Ames Research Center.[5] A backup unit, Pioneer H, is currently on display in the "Milestones of Flight" exhibit at the National Air and Space Museum in Washington, D.C..[6] Many elements of the mission proved to be critical in the planning of the Voyager program.[7]:266–8

#### Spacecraft design

The Pioneer 11 bus measures 36 centimeters (14 in) deep and with six 76-centimeter-long (30 in) panels forming the hexagonal structure. The bus houses propellant to control the orientation of the probe and eight of the twelve scientific instruments. The spacecraft has a mass of 260 kilograms.[1]:42

Orientation of the spacecraft was maintained with six 4.5- N, [8] hydrazine monopropellant thrusters: pair one maintains a constant spin-rate of 4.8 rpm, pair two controls the forward thrust, pair three controls attitude. Information for the orientation is provided by performing conical scanning maneuvers to track Earth in its orbit, [9] a star sensor able to reference Canopus, and two Sun sensors. [1] :42–43
The space probe includes a redundant system transceivers, one attached to the high-gain antenna, the other to an omni-antenna and medium-gain antenna. Each transceiver is 8 watts and transmits data across the S-band using 2110 MHz for the uplink from Earth and 2292 MHz for the downlink to Earth with the Deep Space Network tracking the signal. Prior to transmitting data, the probe uses a convolutional encoder to allow correction of errors in the received data on Earth. [1] :43
Pioneer 11 uses four SNAP-19 radioisotope thermoelectric generators (RTGs) ( see diagram). They are positioned on two three-rod trusses, each 3 meters (9 feet 10 inches) in length and 120 degrees apart. This was expected to be a safe distance from the sensitive scientific experiments carried on board. Combined, the RTGs provided 155 watts at launch, and decayed to 140 W in transit to Jupiter. The spacecraft requires 100 W to power all systems. [1] :44–45
Much of the computation for the mission was performed on Earth and transmitted to the probe, where it is able to retain in memory, up to five commands of the 222 possible entries by ground controllers. The spacecraft includes two command decoders and a command distribution unit, a very limited form of processor, to direct operations on the spacecraft. This system requires that mission operators prepare commands long in advance of transmitting them to the probe. A data storage unit is included to record up to 6,144 bytes of information gathered by the instruments. The digital telemetry unit is then be used to prepare the collected data in one of the thirteen possible formats before transmitting it back to Earth. [1] :38

Pioneer has one additional instrument more than Pioneer 10, a flux-gate magnetometer.[10]

Helium Vector Magnetometer (HVM)
Measures the fine structure of the interplanetary magnetic field, mapped the Jovian magnetic field, and provides magnetic field measurements to evaluate solar wind interaction with Jupiter.[11]
• Principal investigator: Edward Smith / JPL
Peer through a hole in the large dish-shaped antenna to detect particles of the solar wind originating from the Sun.[12]
Charged Particle Instrument (CPI)
Detects cosmic rays in the Solar System.[14]
Cosmic Ray Telescope (CRT)
Collects data on the composition of the cosmic ray particles and their energy ranges.[15]
Geiger Tube Telescope (GTT)
Surveys the intensities, energy spectra, and angular distributions of electrons and protons along the spacecraft's path through the radiation belts of Jupiter and Saturn.[16]

Includes an unfocused Cerenkov counter that detects the light emitted in a particular direction as particles passed through it recording electrons of energy, 0.5 to 12 MeV, an electron scatter detector for electrons of energy, 100 to 400 keV, and a minimum ionizing detector consisting of a solid-state diode that measured minimum ionizing particles (<3 MeV) and protons in the range of 50 to 350 MeV.[17]

• Principal investigator: R. Fillius / University of California San Diego[13]
Meteoroid Detectors
Twelve panels of pressurized cell detectors mounted on the back of the main dish antenna record penetrating impacts of small meteoroids.[18]
• Principal investigator: William Kinard / NASA Langley Research Center[13]
Asteroid/Meteoroid Detector (AMD)
Meteoroid-asteroid detector looks into space with four non-imaging telescopes to track particles ranging from close by bits of dust to distant large asteroids.[19]
• Principal investigator: Robert Soberman / General Electric Company[13]
Ultraviolet Photometer
Ultraviolet light is sensed to determine the quantities of hydrogen and helium in space and on Jupiter and Saturn.[20]
• Principal investigator: Darrell Judge / University of Southern California[13]
Imaging Photopolarimeter (IPP)
The imaging experiment relies upon the spin of the spacecraft to sweep a small telescope across the planet in narrow strips only 0.03 degrees wide, looking at the planet in red and blue light. These strips are then processed to build up a visual image of the planet.[21]
Provides information on cloud temperature and the output of heat from Jupiter and Saturn.[22]
• Principal investigator: Andrew Ingersoll / California Institute of Technology[13]
Triaxial Fluxgate Magnetometer
Measures the magnetic fields of both Jupiter and Saturn. This instrument is not carried on Pioneer 10.[23]
• Principal investigator: Mario Acuna / NASA Goddard Space Flight Center

### Mission profile

Pioneer 11 launching from Launch Complex 36A.
Animation of Pioneer 11 's trajectory from 6 April 1973 to 31 December 1980
Pioneer 11   ·   ·   ·
Animation of Pioneer 11 's trajectory around Jupiter from 30 November 1974 to 5 December 1974
Pioneer 11  ·   ·   ·   ·   ·
Timeline of travel
Date Event
1973-04-06
Spacecraft launched at 02:11:00.
1974-04-19
Passage through the asteroid belt.
1974-11-03
Start Jupiter observation phase.
Time Event
1974-12-02
Encounter with Jovian system.
08:21:00
Callisto flyby at 786,500 km.
22:09:00
Ganymede flyby at 692,300 km.
1974-12-03
03:11:00
Io flyby at 314,000 km.
04:15:00
Europa flyby at 586,700 km.
05:00:21
05:01:01
Jupiter occultation entry.
05:21:19
Jupiter closest approach at 42,828 km.
05:33:52
05:43:03
Jupiter occultation exit.
22:29:00
Amalthea flyby at 127,500 km.
1975-01-01
Phase stop.
1979-07-31
Start Saturn observation phase.
Time Event
1979-08-29
Encounter with Saturnian system.
06:06:10
Iapetus flyby at 1,032,535 km.
11:53:33
Phoebe flyby at 13,713,574 km.
1979-08-31
12:32:33
Hyperion flyby at 666,153 km.
1979-09-01
14:26:56
Descending ring plane crossing.
14:50:55
Epimetheus flyby at 6,676 km.
15:06:32
Atlas flyby at 45,960 km.
15:59:30
Dione flyby at 291,556 km.
16:26:28
Mimas flyby at 104,263 km.
16:29:34
Saturn closest approach at 20,591 km.
16:35:00
Saturn occultation entry.
16:35:57
16:51:11
Janus flyby at 228,988 km.
17:53:32
Saturn occultation exit.
17:54:47
18:21:59
Ascending ring plane crossing.
18:25:34
Tethys flyby at 329,197 km.
18:30:14
20:04:13
Calypso flyby at 109,916 km.
22:15:27
Rhea flyby at 345,303 km.
1979-09-02
18:00:33
Titan flyby at 362,962 km.
1979-10-05
Phase stop.
1979-10-05
Begin Pioneer Interstellar Mission.
[1]:61–94[24][25]

#### Launch and trajectory

The Pioneer 11 probe was launched on April 6, 1973 at 02:11:00 UTC, by the National Aeronautics and Space Administration from Space Launch Complex 36A at Cape Canaveral, Florida aboard an Atlas-Centaur launch vehicle. Its twin probe, Pioneer 10, had launched a year earlier on March 3, 1972. Pioneer 11 was launched on a trajectory directly aimed at Jupiter without any prior gravitational assists.[26] In May 1974, Pioneer was retargeted to fly past Jupiter on a north-south trajectory enabling a Saturn flyby in 1979. The maneuver used 17 pounds of propellant, lasted 42 minutes and 36 seconds and increased Pioneer 11's speed by 230 km/h.[27] It also made two mid-course corrections, on April 11, 1973 and November 7, 1974.[3]

#### Encounter with Jupiter

Pioneer 11 flew past Jupiter in November and December 1974. During its closest approach, on December 2, it passed 42,828 kilometers (26,612 mi) above the cloud tops.[24] The probe obtained detailed images of the Great Red Spot, transmitted the first images of the immense polar regions, and determined the mass of Jupiter's moon Callisto. Using the gravitational pull of Jupiter, a gravity assist was used to alter the trajectory of the probe towards Saturn. On April 16, 1975, following the Jupiter encounter, the micrometer detector was turned off.[3]

#### Saturn encounter

Pioneer 11 passed by Saturn on September 1, 1979, at a distance of 21,000 km from Saturn's cloud tops.

By this time Voyager 1 and Voyager 2 had already passed Jupiter and were also en route to Saturn, so it was decided to target Pioneer 11 to pass through the Saturn ring plane at the same position that the soon-to-come Voyager probes would use in order to test the route before the Voyagers arrived. If there were faint ring particles that could damage a probe in that area, mission planners felt it was better to learn about it via Pioneer. Thus, Pioneer 11 was acting as a "pioneer" in a true sense of the word; if danger were detected, then the Voyager probes could be rerouted further away from the rings, but missing the opportunity to visit Uranus and Neptune in the process.

Pioneer 11 imaged and nearly collided with one of Saturn's small moons, passing at a distance of no more than 4,000 kilometers (2,500 mi). The object was tentatively identified as Epimetheus, a moon discovered the previous day from Pioneer's imaging, and suspected from earlier observations by Earth-based telescopes. After the Voyager flybys, it became known that there are two similarly-sized moons (Epimetheus and Janus) in the same orbit, so there is some uncertainty about which one was the object of Pioneer's near-miss. Pioneer 11 encountered Janus on September 1, 1979 at 14:52 UTC at a distance of 2500 km and Mimas at 16:20 UTC the same day at 103000 km.

Besides Epimetheus, instruments located another previously undiscovered small moon and an additional ring, charted Saturn's magnetosphere and magnetic field and found its planet-size moon, Titan, to be too cold for life. Hurtling underneath the ring plane, the probe sent back pictures of Saturn's rings. The rings, which normally seem bright when observed from Earth, appeared dark in the Pioneer pictures, and the dark gaps in the rings seen from Earth appeared as bright rings.

#### Interstellar mission

On February 25, 1990, Pioneer 11 became the 4th man-made object to pass beyond the orbit of the planets.[28]

#### NASA ends operations

By 1995, Pioneer 11 could no longer power any of its detectors, so the decision was made to shut it down.[29] On September 29, 1995, NASA's Ames Research Center, responsible for managing the project, issued a press release that began, "After nearly 22 years of exploration out to the farthest reaches of the Solar System, one of the most durable and productive space missions in history will come to a close." It indicated NASA would use its Deep Space Network antennas to listen "once or twice a month" for the spacecraft's signal, until "some time in late 1996" when "its transmitter will fall silent altogether." NASA Administrator Daniel Goldin characterized Pioneer 11 as "the little spacecraft that could, a venerable explorer that has taught us a great deal about the Solar System and, in the end, about our own innate drive to learn. Pioneer 11 is what NASA is all about – exploration beyond the frontier."[30] Besides announcing the end of operations, the dispatch provided a historical list of Pioneer 11 mission achievements. NASA terminated routine contact with the spacecraft on September 30, 1995, but continued to make contact for about 2 hours every 2 to 4 weeks.[29] Scientists received a few minutes of good engineering data on 24 November 1995 but then lost final contact once Earth permanently moved out of view of the spacecraft's antenna.[3] Its signal became too faint to hear in 2002.[31]

### Current status

:Pioneer 10 and 11 speed and distance from the Sun

On January 30, 2019, Pioneer 11 was 100.84 AU (1.5085×1010 km; 9.374×109 mi) from the Earth and 100 AU (1.5×1010 km; 9.3×109 mi) from the Sun; and traveling at 11.241 km/s (40,470 km/h; 25,150 mph) (relative to the Sun) and traveling outward at about 2.37 AU per year.[32] The spacecraft is heading in the direction of the constellation Scutum near the current position (August 2017) RA 18h 50m dec -8° 39.5' (J2000.0) close to Messier 26. In 928,000 years it will pass within 0.25pc of the K dwarf TYC 992-192-1.[33]

Pioneer 11 has now been overtaken by the two Voyager probes, launched in 1977, and Voyager 1 is now the most distant object built by humans.[34]

### Pioneer anomaly

Analysis of the radio tracking data from the Pioneer 10 and 11 spacecraft at distances between 20–70 AU from the Sun has consistently indicated the presence of a small but anomalous Doppler frequency drift. The drift can be interpreted as due to a constant acceleration of (8.74 ± 1.33) × 10−10 m/s2 directed towards the Sun. Although it is suspected that there is a systematic origin to the effect, none was found. As a result, there is sustained interest in the nature of this so-called "Pioneer anomaly".[35] Extended analysis of mission data by Slava Turyshev and colleagues has determined the source of the anomaly to be asymmetric thermal radiation and the resulting thermal recoil force acting on the face of the Pioneers away from the Sun,[36] and in July 2012 the group of researchers published their results in the Physical Review Letters scientific journal.[37]

### Pioneer plaque

Pioneer 10 and 11 both carry a gold-anodized aluminum plaque in the event that either spacecraft is ever found by intelligent lifeforms from other planetary systems. The plaques feature the nude figures of a human male and female along with several symbols that are designed to provide information about the origin of the spacecraft.[38]

### Commemoration

In 1991, Pioneer 11 was honored on one of 10 United States Postage Service stamps commemorating unmanned spacecraft exploring each of the then nine planets and the Moon. Pioneer 11 was the spacecraft featured with Jupiter. Pluto was listed as "Not yet explored".[39]

### Gallery

Pioneer 11 and Saturn rings on September 1, 1979
(artist concept)
Pioneer 11 's flyby of Saturn
(artist concept)
Position of Pioneer 11 as of 8 February 2012 showing spacecraft trajectory since launch (simulated view)

Heliocentric positions of the five interstellar probes (squares) and other bodies (circles) until 2020, with launch and flyby dates. Markers denote positions on 1 January of each year, with every fifth year labelled.
Plot 1 is viewed from the north ecliptic pole, to scale; plots 2 to 4 are third-angle projections at 20% scale.
In the SVG file, hover over a trajectory or orbit to highlight it and its associated launches and flybys.

### References

1. Fimmel, R. O.; Swindell, W.; Burgess, E. Pioneer Odyssey. SP-349/396. Washington, D.C.: NASA-Ames Research Center. OCLC 3211441. Retrieved 9 January 2011.
2. ^ http://www.nasa.gov/centers/ames/missions/archive/pioneer.html
3. ^ a b c d "Pioneer 11: In Depth". Retrieved 10 December 2017.
4. ^
5. ^ NASA - The Pioneer Missions
6. ^ "Milestones of Flight". Smithsonian National Air and Space Museum.
7. ^ William E. Burrows, Exploring Space, (New York: Random House, 1990)
8. ^ Wade, Mark. "Pioneer 10-11". Encyclopedia Astronautica. Archived from the original on 2010-11-20. Retrieved 2011-02-08.
9. ^ "Weebau Spaceflight Encyclopedia". 9 November 2010. Retrieved 12 January 2012.
10. ^ "Pioneer 10 & 11". solarviews.com. Retrieved 2018-12-20.
11. ^ "Magnetic Fields". NASA / National Space Science Data Center. Retrieved 2011-02-19.
12. ^ "Quadrispherical Plasma Analyzer". NASA / National Space Science Data Center. Retrieved 2011-02-19.
13. Simpson 2001, p. 146.
14. ^ "Charged Particle Instrument (CPI)". NASA / National Space Science Data Center. Retrieved 2011-02-19.
15. ^ "Cosmic-Ray Spectra". NASA / National Space Science Data Center. Retrieved 2011-02-19.
16. ^ "Geiger Tube Telescope (GTT)". NASA / National Space Science Data Center. Retrieved 2011-02-19.
17. ^ "Jovian Trapped Radiation". NASA / National Space Science Data Center. Retrieved 2011-02-19.
18. ^ "Meteoroid Detectors". NASA / National Space Science Data Center. Retrieved 2011-02-19.
19. ^ "Asteroid/Meteoroid Astronomy". NASA / National Space Science Data Center. Retrieved 2011-02-19.
20. ^ "Ultraviolet Photometry". NASA / National Space Science Data Center. Retrieved 2011-02-19.
21. ^ "Imaging Photopolarimeter (IPP)". NASA / National Space Science Data Center. Retrieved 2011-02-19.
22. ^ "Infrared Radiometers". NASA / National Space Science Data Center. Retrieved 2011-02-19.
23. ^ "Jovian Magnetic Field". NASA / National Space Science Data Center. Retrieved 2013-09-24.
24. ^ a b "Pioneer 11 Mission Information". Archived from the original on 21 July 2011. Retrieved 23 January 2011.
25. ^ Muller, Daniel. "Pioneer 11 Full Mission Timeline". Daniel Muller. Retrieved 9 January 2011.
26. ^ http://www.nasa.gov/sites/default/files/images/739459main_ACD97-0036-2.jpg
27. ^ "Pioneer 11 Successfully Retargeted for Saturn". New Scientist. 9 May 1974. Retrieved 5 December 2017.
28. ^ "Pioneer 11 Is Reported to Leave Solar System". 25 February 1990. Retrieved 3 December 2017.
29. ^ a b "Farewell to a Pioneer". Science News. 14 October 1995.
30. ^ "Pioneer 11 to End Operations after Epic Career". NASA / Ames Research Center. September 29, 1995. Retrieved August 7, 2011.
31. ^ Howell, Elizabeth. "Pioneer 11: Up Close with Jupiter & Saturn". Space.com. Retrieved 10 December 2017.
32. ^ "Archived copy". Archived from the original on 2015-07-21. Retrieved 2015-07-19.CS1 maint: Archived copy as title (link)
33. ^ "Future stellar flybys of the Voyager and Pioneer spacecraft". RNAAS 3, 59. 3 April 2019. Retrieved 3 April 2019.
34. ^ Where are the Voyagers
35. ^ Britt, Robert Roy (October 18, 2004). "The Problem with Gravity: New Mission Would Probe Strange Puzzle". Space.com. Retrieved 2011-06-07. The discrepancy caused by the anomaly amounts to about 248,500 miles (399,900 kilometres), or roughly the distance between Earth and the Moon. That's how much farther the probes should have traveled in their 34 years, if our understanding of gravity is correct.
36. ^ "Pioneer Anomaly Solved!". The Planetary Society. Retrieved 2012-04-20.
37. ^ Support for the thermal origin of the Pioneer anomaly, Slava G. Turyshev et al., Physical Review Letters, accepted 11 April 2012, accessed 19 July 2012
38. ^ Carl Sagan; Linda Salzman Sagan & Frank Drake (1972-02-25). "A Message from Earth" (PDF). Science. 175 (4024): 881–884. Bibcode:1972Sci...175..881S. doi:10.1126/science.175.4024.881. PMID 17781060. Paper on the background of the plaque. Pages available online: 1, 2, 3, 4
39. ^ Kronish, Syd (27 October 1991). "Space Launches are Featured". Retrieved 5 December 2017.