Explorer 45

Last updated

Explorer 45
EXPLORER 45.jpg
Explorer 45 (SSS-A) satellite
NamesSSS-A
S-Cubed A
Small Scientific Satellite-A
Mission type Space physics
Operator NASA
COSPAR ID 1971-096A
SATCAT no. 05598
Mission duration3 years (achieved)
Spacecraft properties
SpacecraftExplorer XLV
Spacecraft typeSmall Scientific Satellite
Bus SSS
Launch mass52 kg (115 lb)
Start of mission
Launch date15 November 1971,
05:52:00 GMT [1]
Rocket Scout B (S-163CR)
Launch site Broglio Space Center,
San Marco platform
Contractor Vought
Entered service15 November 1971
End of mission
Deactivated30 September 1974
Last contact30 September 1974
Decay date10 January 1992
Orbital parameters
Reference system Geocentric orbit [2]
Regime Highly elliptical orbit
Perigee altitude 224 km (139 mi)
Apogee altitude 27,031 km (16,796 mi)
Inclination 3.50°
Period 469.30 minutes
Instruments
AC Electric Field Measurement
Channel Electron Multipliers with Electrostatic Analyzers
DC Electric Field Measurement
Fluxgate Magnetometers
Search Coil Magnetometers
Solid-State Detectors
Solid-State Proton-Alpha Particle Telescopes
Explorer program
 

Explorer 45 (also called as SSS-A and S-Cubed A) was a NASA satellite launched as part of Explorer program. Explorer 45 was the only one to be released from the program Small Scientific Satellite. [3] [4]

Contents

Scientific objectives

Explorer 45 was designed to perform a wide variety of investigations within the magnetosphere with regards to particle fluxes, electric fields, and magnetic fields. Its primary scientific objectives were:

Spacecraft

Explorer 45 had the capability for complete inflight control of the data format through the use of an onboard set of stored program instructions. These instructions governed the collection of data and were reprogrammable via ground command. The antenna system consisted of four dipole antennas spaced 90° apart on the surface of the spacecraft cover. The satellite contained two transmitters, one for digital (PCM) data at 446 bps, and the other for either the digital data or wideband analog data from 30-Hz to 10-kHz from the ac electric field probes and from one search coil sensor. The command system handled 80 commands for controlling the spacecraft and experiment functions, as well as for flight program loads for the data processing system. The antenna system consisted of four dipole antennas spaced 90° apart on the surface of the spacecraft cover. The satellite power system consisted of a rechargeable battery and an array of solar cells. The spin rate was about 7 rpm, and the spin axis lay in the spacecraft orbital plane which was approximately the same as the Earth's equatorial plane. The initial local time of apogee was about 21.8 hours and the line of apsides moved around toward the Sun at an initial rate of 12° per month. The satellite was operationally turned off on 30 September 1974, after approximately 3 years of successful and productive operation. [3]

Experiments

AC Electric Field Measurement

The electric dipole antenna consisted of two boom-mounted graphite coated spheres, 13.97 cm (5.50 in) in diameter, with a center-to-center separation of 5.08 m (16.7 ft). Each sphere was connected to a high-input-impedance (capacitance approximately equal to 10 pF, resistance approximately equal to 50 megohms), unity-gain preamplifier mounted on the boom about halfway between the center of the sphere and the center of the spacecraft. The axis of the antenna was perpendicular to the spacecraft spin axis. The electronics for the electric field experiment consisted of a step-frequency analyzer and a wideband receiver. The spectrum analyzer had fifteen narrowband frequency channels with center frequencies logarithmically spaced from 35-Hz to 100-kHz and one wideband frequency channel with a bandpass of about 100-Hz to 10-kHz. The four highest frequency narrowband filters of the step frequency analyzer had bandwidths of ± 7.5% of their center frequencies and the remaining narrowband filters had bandwidths of ± 15.0% of their center frequencies. The filter outputs were sequentially switched into an 80-dB logarithmic detector with a measurement sensitivity of 10 microvolts/m. The wideband receiver was an automatic gain control receiver with a bandwidth from 100-Hz to 10-kHz. The output of the wideband receiver modulated a special purpose telemetry transmitter. The wideband data was recorded on the ground and then processed by a spectrum analyzer to produce high-resolution frequency-time spectrograms. The wideband system was ormally operated one orbit out of three, but it could be operated continuously for special periods. [5]

Channel Electron Multipliers with Electrostatic Analyzers

This experiment used cylindrical curved-plate electrostatic analyzers in conjunction with channel electron multipliers to study ion and electron directional intensities in 8 or 16 contiguous energy intervals in the energy range 800-eV to 25-keV. Under normal operation, the voltage steps were synchronized to either the half roll or full roll of the satellite. Dual detector systems were used to extend the dynamic range of the instrument. A complete set of measurements was obtained every 64-seconds. This period was programmable. There were two electrostatic analyzers which looked along the spin axis. Both were capable of measuring ions or electrons as selected by ground command. One measured particles at 2-keV, the other at 5-keV. [6]

DC Electric Field Measurement

The electric field antenna consisted of two 13.97 cm (5.50 in) in diameter metal spheres mounted on the ends of two booms with a 5.08 m (16.7 ft) separation. Determination of the potential difference between the spheres yielded electric fields with a sensitivity of 0.1 mV/m. The rotation of the spacecraft allowed a two-component DC measurement to be made. Over most of the orbit the DC measurements were contaminated by spacecraft photosheath-induced potentials and should not be used for determination of DC electric fields. A calibration plate on the spacecraft was used to change the spacecraft potential, thus checking on sheath overlap errors. In addition to the DC measurement, four rms spectrometer channels and a broad-band channel sampled low-frequency variations. The rms spectrometer channels sampled low-frequency variations from 0.3 to 1, 1 to 3, 3 to 10, and 10 to 30-Hz. About 1300 orbits of data were obtained, covering magnetic local times from 08:00 to 23:00 hours through the noon sector. The instrument was used to locate the plasmapause because its amplifiers became saturated by the fields within the spacecraft photosheath when the electron density was below about 60 per cc. About 900 measurements were obtained of the plasmapause boundary throughout the useful lifetime of the instrument. [7]

Fluxgate Magnetometers

This experiment was designed to measure the vector magnetic field and fluctuations over the spacecraft's orbit. This set of magnetometers consisted of a triaxial fluxgate system. These, along with a commandable flipper mechanism to check zero levels, were housed in the sphere at the end of the single boom extending 76 cm (30 in) along the spin axis. This system measured the vector magnetic field from DC to 10-Hz with a sensitivity of less than 5 nT. The magnetic field was sampled 30 times each second. The experiment functioned normally until the latter part of March 1973 when a switch in the spacecraft analog multiplexer began to fail. No useful data were obtained after that time. [8]

Search Coil Magnetometers

This experiment consisted of two perpendicular search coil magnetometers, each mounted on a 61 cm (24 in) radial boom. The plane of one magnetometer was perpendicular to the spacecraft spin axis, and the plane of the other was parallel to the spacecraft spin axis. This system measured magnetic fluctuations between 1 and 3000-Hz. The search coil outputs were routed to sets of filters, each of which was nominally sampled once each second. The experiment functioned normally until the latter part of March 1973 when a switch in the spacecraft analog multiplexer (which affects analog to digital conversion) began to fail. After that time, the only reliable data were analog broad-band data. [9]

Solid-State Detectors

The solid-state electron detector was a magnetic spectrometer with an 800 g (28 oz) magnet, and four 300-micrometer, 0.25-cm2, rectangular, surface barrier, solid-state detectors. Electron intensities were measured in the energy ranges 35 to 70 keV, 75 to 125 keV, 120 to 240 keV, and 240 to 560 keV. After March 1973, due to a failure in the spacecraft analog multiplexer, analog data were not available and the actual energy levels could not be determined without special effort. [10]

Solid-State Proton-Alpha Particle Telescopes

This experiment contained two telescopes, each consisting of two surface barrier solid-state silicon detector elements. The low-energy range telescope had detectors of thicknesses 100 and 300 micrometers, and was mounted behind a 2.2 kg (4.9 lb) broom magnet to sweep out electrons with energies less than 300-keV. This telescope measured the flux of protons in six channels covering the energy range 24.3 to 300-keV. The heavy ion telescope had detectors of thicknesses 3.4 and 100 micrometres. This telescope uniquely identified the presence of protons, alpha particles (Z=2), and two groups of heavier ions, (lithium, beryllium, boron) and (carbon, nitrogen, oxygen), plus ions with Z>=9. The heavy ion telescope measured proton fluxes in six channels covering the energy range 365 to 872-keV, and the fluxes of alpha particles in the energy ranges 1.16 to 1.74-keV and 1.74 to 3.15-keV. It measured the fluxes of lithium, berrelyum, and boron ions in the ranges 3.6 to 7.1-MeV, 6.1 to 9.7-MeV, and 8.7 to 12.2-MeV, respectively, and the fluxes of C, N, and O ions in the ranges 12.1 to 15.7-MeV, 15.6 to 19.2-MeV, and 19.1 to 22.7-MeV, respectively. And it measured the flux of Z>=9 ions with energies > 20-MeV. In addition, electrons of energy greater than 300-keV were detected via the coincidence mode of the low-energy range telescope. Both telescopes were mounted at 90° to the satellite spin axis, and had full conical viewing angles of about 11°. [11]

Launch

Explorer 45 as launched on 15 November 1971, at 05:52:00 GMT, from the San Marco platform of the Broglio Space Center, Kenya, with a Scout B launch vehicle. [1]

Atmospheric entry

Explorer 45 reentered in the atmosphere on 10 January 1992. [2]

See also

Related Research Articles

Explorer 35 NASA satellite of the Explorer program

Explorer 35,, was a spin-stabilized spacecraft built by NASA as part of the Explorer program. Designed for the study of the interplanetary plasma, magnetic field, energetic particles, and solar X-rays, from lunar orbit.

Explorer 6 NASA Earth science satellite launched in 1959

Explorer 6, or S-2, was an American satellite of NASA, launched on 7 August 1959. It was a small, spheroidal satellite designed to study trapped radiation of various energies, galactic cosmic rays, geomagnetism, radio propagation in the upper atmosphere, and the flux of micrometeorites. It also tested a scanning device designed for photographing the Earth's cloud cover. On 14 August 1959, Explorer 6 took the first photos of Earth from a satellite.

<i>Wind</i> (spacecraft) NASA probe to study solar wind, at L1 since 1995

The Global Geospace Science (GGS) Wind satellite is a NASA science spacecraft launched on November 1, 1994, at 09:31 UTC, from launch pad 17B at Cape Canaveral Air Force Station (CCAFS) in Merritt Island, Florida, aboard a McDonnell Douglas Delta II 7925-10 rocket. Wind was designed and manufactured by Martin Marietta Astro Space Division in East Windsor, New Jersey. The satellite is a spin-stabilized cylindrical satellite with a diameter of 2.4 m and a height of 1.8 m.

Explorer 52 NASA satellite of the Explorer program

Explorer 52, also known as Hawkeye-1, Injun-F, Neutral Point Explorer, IE-D, Ionospheric Explorer-D, was a NASA satellite launched on 3 June 1974, from Vandenberg Air Force Base on a Scout E-1 launch vehicle.

Explorer 33 NASA satellite of the Explorer program

Explorer 33, also known as IMP-D and AIMP-1, was a spacecraft in the Explorer program launched by NASA on 1 July 1966 on a mission of scientific exploration. It was the fourth satellite launched as part of the Interplanetary Monitoring Platform series, and the first of two "Anchored IMP" spacecraft to study the environment around Earth at lunar distances, aiding the Apollo program. It marked a departure in design from its predecessors, IMP-A through IMP-C. Explorer 35 was the companion spacecraft to Explorer 33 in the Anchored IMP program, but Explorer 34 (IMP-F) was the next spacecraft to fly, launching about two months before AIMP-E, both in 1967.

Explorer 18 NASA satellite of the Explorer program

Explorer 18, also called IMP-A, IMP-1, Interplanetary Monitoring Platform-1 and S-74, was a NASA satellite launched as part of the Explorer program. Explorer 18 was launched on 27 November 1963 from Cape Canaveral Air Force Station (CCAFS), Florida, with a Thor-Delta C launch vehicle. Explorer 18 was the first satellite of the Interplanetary Monitoring Platform (IMP). Explorer 21 (IMP-B) launched in October 1964 and Explorer 28 (IMP-C) launched in May 1965 also used the same general spacecraft design.

Explorer 14 NASA satellite of the Explorer program

Explorer 14, also called EPE-B, was a spin-stabilized, solar-cell-powered spacecraft instrumented to measure cosmic-ray particles, trapped particles, solar wind protons, and magnetospheric and interplanetary magnetic fields. It was the second of the S3 series of spacecraft, which also included Explorer 12, 14, 15, and 26. It was launched on 2 October 1962, aboard a Thor-Delta launch vehicle.

ISEE-1 Space probe used to study magnetic fields near the Earth

The ISEE-1 was a Explorer-class mother spacecraft, International Sun-Earth Explorer-1, was part of the mother/daughter/heliocentric mission. ISEE-1 was a 340.2 kg (750 lb) space probe used to study magnetic fields near the Earth. ISEE-1 was a spin-stabilized spacecraft and based on the design of the prior IMP series of spacecraft. ISEE-1 and ISEE-2 were launched on 22 October 1977, and they re-entered on 26 September 1987.

ISEE-2 Space probe used to study magnetic fields near the Earth

The ISEE-2 was a Explorer-class daughter spacecraft, International Sun-Earth Explorer-2, was part of the mother/daughter/heliocentric mission. ISEE-2 was a 165.78 kg (365.5 lb) space probe used to study magnetic fields near the Earth. ISEE-2 was a spin-stabilized spacecraft and based on the design of the prior IMP series of spacecraft. ISEE-1 and ISEE-2 were launched on 22 October 1977, and they re-entered on 26 September 1987.

Explorer 12 NASA satellite of the Explorer program

Explorer 12, also called EPE-A and as S3), was a United States satellite built to measure the solar wind, cosmic rays, and the Earth's magnetic field. It was the first of the S3 series of spacecraft, which also included Explorer 12, 14, 15, and 26. It was launched on 16 August 1961, aboard a Thor-Delta launch vehicle. It ceased transmitting on 6 December 1961 due to power failure.

Explorer 26 NASA satellite of the Explorer program

Explorer 26 was a NASA satellite launched on 21 December 1964, as part of NASA's Explorer program. Its primary mission was to study the Earth's magnetic field.

Explorer 28 NASA satellite of the Explorer program

Explorer 28, also called IMP-C, IMP-3 and Interplanetary Monitoring Platform-3, was a NASA satellite launched on 29 May 1965 to study space physics, and was the third spacecraft launched in the Interplanetary Monitoring Platform program. It was powered by chemical batteries and solar panels. There were 7 experiments on board, all devoted to particle studies. Performance was normal until late April 1967, when intermittent problems began. It stayed in contact until 12 May 1967, when contact was lost. The orbit decayed until it re-entered the atmosphere on 4 July 1968. The spacecraft design was similar to its predecessors Explorer 18 (IMP-A), launched in November 1963, and Explorer 21 (IMP-B), launched in October 1964, though this satellite was a few kilograms lighter. The successor Explorer 33 (IMP-D) began the use of a new design.

Explorer 15 NASA satellite of the Explorer program

Explorer 15, also called EPE-C, was an American satellite launched as part of the Explorer program. Explorer 15 was launched on 27 October 1962, at Cape Canaveral Air Force Station, Florida, United States, with a Thor-Delta A.

Explorer 21 NASA satellite of the Explorer program

Explorer 21, also called IMP-B, IMP-2 and Interplanetary Monitoring Platform-2, was a NASA satellite launched as part of Explorer program. Explorer 21 was launched on 4 October 1964, at 03:45:00 GMT from Cape Canaveral (CCAFS), Florida, with a Thor-Delta C launch vehicle. Explorer 21 was the second satellite of the Interplanetary Monitoring Platform, and used the same general design as its predecessor, Explorer 18 (IMP-A), launched the previous year, in October 1964. The following Explorer 28 (IMP-C), launched in May 1965, also used a similar design.

Explorer 34 NASA satellite of the Explorer program

Explorer 34, was a NASA satellite launched as part of Explorer program. Explorer 34 as launched on 24 May 1967 from Vandenberg Air Force Base, California, with Thor-Delta E1 launch vehicle. Explorer 34 was the fifth satellite launched as part of the Interplanetary Monitoring Platform program, but was known as "IMP-4" because the preceding launch was more specifically part of the "Anchored IMP" sub-program. The spacecraft was put into space between the launches of Explorer 33 in 1966 and Explorer 35 in July 1967, but the next satellite to use Explorer 34's general design was Explorer 41, which flew in 1969.

Explorer 40 NASA satellite of the Explorer program

Explorer 40, was a NASA magnetically aligned satellite launched simultaneously with Explorer 39 (AD-C) using a Scout B launch vehicle. This was NASA's a dual-satellite launch.

Explorer 41 NASA satellite of the Explorer program

Explorer 41, also called as IMP-G and IMP-5, was a NASA satellite launched as part of Explorer program. Explorer 41 as launched on 21 June 1969 on Vandenberg AFB, California, with a Thor-Delta E1 launch vehicle. Explorer 41 was the seventh satellite launched as part of the overall Interplanetary Monitoring Platform series, though it received the post-launch designation "IMP-5" because two previous flights had used the "AIMP" designation instead. It was preceded by the second of those flights, Explorer 35, launched in July 1967. Its predecessor in the strict IMP series of launches was Explorer 34, launched in May 1967, which shared a similar design to Explorer 41. The next launch was of an IMP satellite was Explorer 43 in 1971.

Explorer 43 NASA satellite of the Explorer program

Explorer 43, also called as IMP-I and IMP-6, was a NASA satellite launched as part of Explorer program. Explorer 43 was launched on 13 March 1971 from Cape Canaveral Air Force Station (CCAFS), with a Thor-Delta M6 launch vehicle. Explorer 43 was the sixth satellite of the Interplanetary Monitoring Platform.

Explorer 47 NASA satellite of the Explorer program

Explorer 47, was a NASA satellite launched as part of Explorer program. Explorer 47 was launched on 23 September 1972 from Cape Canaveral, Florida, with a Thor-Delta 1604. Explorer 47 was the ninth overall launch of the Interplanetary Monitoring Platform series, but received the launch designation "IMP-7" because two previous "Anchored IMP" flights had used "AIMP" instead.

Explorer 50 NASA satellite of the Explorer program

Explorer 50, also known as IMP-J or IMP-8, was a NASA satellite launched to study the magnetosphere. It was the eighth and last in a series of the Interplanetary Monitoring Platform.

References

  1. 1 2 "Launch Log". Jonathan's Space Report. 21 July 2021. Retrieved 14 November 2021.
  2. 1 2 "Trajectory: Explorer 45 (S-Cubed A) 1971-096A". NASA. 28 October 2021. Retrieved 14 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  3. 1 2 3 "Display: Explorer 45 (SSS-A) 1971-096A". NASA. 28 October 2021. Retrieved 14 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  4. "SSS". Encyclopedia Astronautica. 2011. Retrieved 19 June 2018.
  5. "Experiment: AC Electric Field Measurement". NASA. 28 October 2021. Retrieved 15 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  6. "Experiment: Channel Electron Multipliers with Electrostatic Analyzers". NASA. 28 October 2021. Retrieved 15 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  7. "Experiment: DC Electric Field Measurement". NASA. 28 October 2021. Retrieved 15 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  8. "Experiment: Fluxgate Magnetometers". NASA. 28 October 2021. Retrieved 15 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  9. "Experiment: Search Coil Magnetometers". NASA. 28 October 2021. Retrieved 15 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  10. "Experiment: Solid-State Detectors". NASA. 28 October 2021. Retrieved 15 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .
  11. "Experiment: Solid-State Proton-Alpha Particle Telescopes". NASA. 28 October 2021. Retrieved 15 November 2021.PD-icon.svgThis article incorporates text from this source, which is in the public domain .