Solar Maximum Mission

Satellite to investigate Solar phenomena

Solar Maximum Mission
Spacecraft properties
Solar Maximum Mission.

Mission type	Solar physics
Operator	NASA
COSPAR ID	1980-014A
SATCAT no.	11703
Mission duration	Final: 9 years, 9 months, 17 days


Bus	Multimission Modular Spacecraft
Manufacturer	Fairchild Industries
Launch mass	2,315.0 kilograms (5,103.7 lb)
Dimensions	4 by 2.3 metres (13.1 by 7.5 ft)


Start of mission
Launch date	February 14, 1980, 15:57:00 (1980-02-14UTC15:57Z) UTC
Rocket	Delta 3910
Launch site	Cape Canaveral LC-17A


End of mission
Decay date	December 2, 1989 (1989-12-03)


Orbital parameters
Reference system	Geocentric
Regime	Low Earth
Eccentricity	0.00029
Perigee altitude	508.0 kilometers (315.7 mi)
Apogee altitude	512.0 kilometers (318.1 mi)
Inclination	28.5 degrees
Period	94.80 minutes
Mean motion	15.19

The Solar Maximum Mission satellite (or SolarMax) was designed to investigate Solar phenomena, particularly solar flares. It was launched on February 14, 1980. The SMM was the first satellite based on the Multimission Modular Spacecraft bus manufactured by Fairchild Industries, a platform which was later used for Landsats 4 and 5^[1] as well as the Upper Atmosphere Research Satellite.

After an attitude control failure in November 1980 it was put in standby mode until April 1984 when it was repaired by a Shuttle mission.

The Solar Maximum Mission ended on December 2, 1989, when the spacecraft re-entered the atmosphere and burned up over the Indian Ocean.^[2]

Instruments

Experiments on board the Solar Maximum Mission
Name	Target	Principal Investigator
Coronagraph/Polarimeter: 446.5–658.3 nm, 1.5- 6 sq.solar radii fov, 6.4 arcsec res.	Solar corona, prominences, and flares	House, Lewis L., High Altitude Observatory
Ultraviolet Spectrometer and polarimeter 175.0–360.0 nm raster imager, 0.004 nm sp.res.	Solar UV, Earth's atmosphere	Tandberg-Hanssen, Einar A., NASA Marshall Space Flight Center
Soft X-ray Polychromator: raster imager, crystal spectrom. in parts of 0.14–2.25 nm	Solar flares, active solar regions	Acton, Loren W., Lockheed Palo Alto, Culhane, J University College, London, Leonard, Gabriel, Alan-Henri, Rutherford Appleton Laboratory
Hard X-ray Imaging Spectrometer: fov 6.4 arcmin, 8 or 32 arcsec res, 3.5–30 keV	Solar active regions and flares	de Jager, Cornelis, University of Utrecht
Hard X-ray Burst Spectrometer: CsI(Na), 15 energy channels covering 20–260 keV	Solar flares and active regions	Frost, Kenneth J., NASA Goddard Space Flight Center
Gamma-ray Spectrometer: NaI(T1),0.01-100 MeV in 476 channels, 16.4 s per spectrum	solar gamma-rays	Chupp, Edward L, University of New Hampshire
Active Cavity Radiometer Irradiance Monitor: 0.001-1000 micrometer solar flux	solar irradiance	Willson, Richard C, NASA Jet Propulsion Laboratory

Failure and repair

The white-light coronagraph/polarimeter (C/P) took coronal images for about six months from March 1980 before suffering an electronics failure in September that prevented operation.^[2]

In November 1980, the second of four fuses in SMM's attitude control system failed, causing it to rely on its magnetorquers in order to maintain attitude. In this mode, only three of the seven instruments on board were usable, as the others required the satellite to be accurately pointed at the Sun. The use of the satellite's magnetorquers prevented the satellite from being used in a stable position and caused it to "wobble" around its nominally sun-pointed attitude.^[3] SMM was left in standby mode for 3 years.^[2]

The first orbiting, uncrewed satellite to be repaired in space, SMM was notable in that its useful life compared with similar spacecraft was significantly increased by the direct intervention of a crewed space mission. During STS-41-C in April 1984, the Space Shuttle Challenger rendezvoused with the SMM, astronauts James van Hoften and George Nelson attempted to use the Manned Maneuvering Unit to capture the satellite and to bring it into the orbiter's payload bay for repairs and servicing. The plan was to use an astronaut-piloted Maneuvering Unit to grapple the satellite with the Trunnion Pin Attachment Device (TPAD) mounted between the hand controllers of the Maneuvering Unit, null its rotation rates, and allow the Shuttle to bring it into the Shuttle's payload bay for stowage. Three attempts to grapple the satellite using the TPAD failed. The TPAD jaws could not lock onto Solar Max because of an obstructing grommet on the satellite not included in its blueprints.

This led to an improvised plan which nearly ended the satellite's mission. The improvisation had the astronaut use his hands to grab hold of a solar array and null the rotation with a push from the Maneuvering Unit's thrusters. Instead, this attempt induced higher rates and in multiple axes; the satellite was tumbling out of control and quickly losing battery life. SMM Operations Control Center engineers shut down all non-essential satellite subsystems and with a bit of luck were able to recover the satellite minutes before total failure. The ground support engineers then stabilized the satellite and nulled its rotation rates for capture with the Shuttle's robotic arm. This proved to be a much better plan. The satellite had been fitted with one of the arm's grapple fixtures so that the robotic arm was able to capture and maneuver it into the shuttle's payload bay for repairs.^[4]

During the mission, the SMM's entire attitude control system module and the electronics module for the coronagraph/polarimeter instrument were replaced, and a gas cover was installed over the X-ray polychromator.^[4] Their successful work added five more years to the lifespan of the satellite. The mission was depicted in the 1985 IMAX movie The Dream Is Alive.

Discovery of comets

10 comets were discovered in images from the SMM.^[5]

Designation	Observation date	Discoverer^[6]
C1987 T2 (SMM-1)	Oct 5,1987	Dr Orville Chris St. Cyr
C/1987 U4 (SMM-2)	Oct 17,1987	O. C. St. Cyr
1988l (SMM-3)	Jun 27, 1988	O. C. St. Cyr
1988m (SMM-4)	Aug 21, 1988	David Kobe, C. Waugh
1988n (SMM-5)	Oct 11-12 1988	O.C. St. Cyr^[7]
1988p (SMM-6)	Nov 18, 1988	O.C. St. Cyr^[8]
1988q (SMM-7)	Oct 24, 1988	Andrew L. Stanger^[9]
1989m (SMM-8)	Jun 2, 1989	O.C. St. Cyr, David L. Kobe ^[10]
1989q (SMM-9)	Jul 8,1989	O.C. St. Cyr^[11]
1989x (SMM-10)	Sep 28,1989	O.C. St. Cyr^[12]

Findings

A coronal transient as seen by the SMM on May 5, 1980.

Significantly, the SMM's ACRIM instrument package showed that contrary to expectations, the Sun is actually brighter during the sunspot cycle maximum (when the greatest number of dark 'sunspots' appear). This is because sunspots are surrounded by bright features called faculae, which more than cancel the darkening effect of the sunspot.

The major scientific findings from the SMM are presented in several review articles in a monograph.^[13]

End of mission

SMM's orbit slowly decayed due to atmospheric drag taking it down into denser regions.

The March 1989 geomagnetic storm was reported to have led to SMM dropping half a kilometre at the start of the storm and 5 kilometres over the whole period.^[14]

SMM lost attitude control on November 17, 1989, and re-entry and burn-up occurred on December 2, 1989, over the Indian Ocean.^[2]

References

^ Suzuki, Masaharu (11 February 1999). "TOPEX/Poseidon – Description of Mission". University of Texas. Archived from the original on 20 November 2013. Retrieved 9 July 2013. The satellite bus was taken from the Multimission Modular Spacecraft (MMS), which has been proven on previous MMS-based missions: the Solar Maximum Mission and Landsat 4 and 5.
^ ^a ^b ^c ^d SOLAR MAXIMUM MISSION (SMM)
^ "STS-41-C Press Kit" (PDF). NASA. Retrieved 9 July 2013. All four of those instruments require pointing accuracy from the spacecraft and could not function effectively with the spacecraft spinning through space with its longitudinal axis pointed toward the sun, as it has since the attitude control system failure.
^ ^a ^b "STS-41-C Press Kit" (PDF). NASA. Retrieved 9 July 2013. Repairs to be made during the mission include replacing the attitude control system module, replacing the main electronics box on the Polarimeter/Polarimeter, and placing a cover over the gas vent of the X-Ray Polychrometer.
^ "Sungrazing comets observed by the solar maximum mission coronagraph". Archived from the original on 2022-07-02. Retrieved 2022-07-02.
^ My Solwind Comets (by Rainer Kracht)
^ [url=https://ui.adsabs.harvard.edu/abs/1988IAUC.4668....1S/abstract }}
^ [https://ui.adsabs.harvard.edu/abs/1988IAUC.4684....1S/abstract }}
^ [https://ui.adsabs.harvard.edu/abs/1988IAUC.4692....1S/abstract }}
^ [http://www.cbat.eps.harvard.edu/iauc/04700/04793.html }}
^ [https://ui.adsabs.harvard.edu/abs/1989IAUC.4815....1S/abstract }}
^ [https://ui.adsabs.harvard.edu/abs/1989IAUC.4884....1S/abstract }}
^ Strong, Keith T.; Saba, Julia L. R.; Haisch, Bernhard M.; Schmelz, Joan T. (1999). Strong KT; Saba JLR; Haisch BM; Schmelz JT (eds.). The many faces of the sun : a summary of the results from NASA's Solar Maximum Mission. New York: Springer. Bibcode:1999mfs..conf.....S.
^ "Effects of the March 1989 Solar Activity", by Allen, Frank, Sauer, Reiff, in Eos, November 14, 1989 p. 1488

External links

Wikimedia Commons has media related to Solar Maximum Mission.

HEASARC, SMM
Marshall Space Flight Center, SMM
SMM C/P Coronal Mass Ejections
Total Solar Irradiance ACRIM

Solar space missions

List of heliophysics missions - List of solar telescopes

Current

ACE (since 1997)
Aditya-L1 (since 2023)
ASO-S [fr] (since 2022)
CHASE (Xihe) (since 2021)
DSCOVR (since 2015)
Hinode (Solar-B) (since 2006)
IRIS (since 2013)
Parker Solar Probe (since 2018)
Solar and Heliospheric Observatory (since 1995)
Solar Dynamics Observatory (since 2010)
Solar Orbiter (since 2020)
STEREO (since 2006)
Wind (since 1994)

Past

Apollo Telescope Mount
Coronas F (Koronas F)
EURECA
ESRO 2B
Genesis
GOES 13
Helios
Hinotori (Astro-A)
IMP-8
Intercosmos 26 (Koronas I)
ISEE-1
ISEE-2
ICE / ISEE-3
Koronas-Foton
MinXSS1
MinXSS2
Orbiting Solar Observatory
- OSO 1
- OSO 2/OSO B
- OSO 3
- OSO 4
- OSO 5
- OSO 6
- OSO 7
- OSO 8
- Solwind
PICARD
Pioneer 5
Pioneer 6, 7, 8 and 9
PROBA-2
Prognoz 6
RHESSI
SOLAR
SolarMax
Spartan 201
Taiyo (SRATS)
TRACE
Ulysses
Yohkoh (Solar-A)

Planned

Electrojet Zeeman Imaging Explorer (2024)
PROBA-3 (2024)
PUNCH (2025)
SWFO-L1 (2025)
TRACERS (2025)
Solar-C EUVST (2028)
Vigil (2020s)

Proposed

ADAHELI
SETH
Sundiver

Cancelled

Lost

Sun-Earth

Category

NASA Goddard Space Flight Center

Main articles

Facilities

Wallops Flight Facility (WFF)
Goddard Institute for Space Studies (GISS)
Columbia Scientific Balloon Facility (CSBF)
Spacecraft Magnetic Test Facility
Katherine Johnson Independent Verification and Validation Facility (IV&V)
Spacecraft Fabrication Facility

Notable missions
and programs

People

Leadership	Dennis J. Andrucyk (Director) Anne L. Kinney (Deputy Center Director) Christyl Johnson (Deputy Director, Technology and Research Investments) Ray Rubilotta (Associate Center Director)
Notable scientists and engineers	David Louis Band Robert Bindschadler Fred Espenak Gene Carl Feldman Orlando Figueroa James Hansen Marc Kuchner Lissette Martinez John C. Mather Nancy Roman

v t e ← 1979 Orbital launches in 1980 1981 →
Kosmos 1149 Molniya 1-46 OPS 6293 Kosmos 1150 Kosmos 1151 Kosmos 1152 Kosmos 1153 Kosmos 1154 Kosmos 1155 OPS 2581 OPS 5117 Kosmos 1156 Kosmos 1157 Kosmos 1158 Kosmos 1159 Kosmos 1160 Kosmos 1161 Kosmos 1162 Kosmos 1163 Kosmos 1164 SolarMax Tansei-4 Gran' No.16L Kosmos 1165 Ayame-2 OPS 7245 (SSU-1, SSU-2, SSU-3) Kosmos 1166 Kosmos 1167 Kosmos 1168 Kosmos 1169 Progress 8 Kosmos 1170 Kosmos 1171 Soyuz 35 Kosmos 1172 Kosmos 1173 Kosmos 1174 Kosmos 1175 OPS 5118 Progress 9 Kosmos 1176 Kosmos 1177 Kosmos 1178 Kosmos 1179 Kosmos 1180 Kosmos 1181 Kosmos 1182 CAT-2 Firewheel FIRE B FIRE C FIRE D FIRE E Amsat-P3A Soyuz 36 Kosmos 1183 NOAA-B Kosmos 1184 Soyuz T-2 Kosmos 1185 Kosmos 1186 Kosmos 1187 Gorizont No.15L Kosmos 1188 Meteor-Priroda No.3-1 OPS 3123 Molniya 1-47 Kosmos 1189 Progress 10 Kosmos 1190 Kosmos 1191 Kosmos 1192 Kosmos 1193 Kosmos 1194 Kosmos 1195 Kosmos 1196 Kosmos 1197 Kosmos 1198 Kosmos 1199 Kosmos 1200 Ekran No.19L DMSP-5D1 F5 Kosmos 1201 Rohini RS-1B Molniya 3-13 Soyuz 37 Kosmos 1202 Kosmos 1203 Kosmos 1204 Kosmos 1205 Kosmos 1206 Kosmos 1207 Kosmos 1208 Meteor 2-06 GOES 4 Soyuz 38 Kosmos 1210 Kosmos 1211 Kosmos 1212 Progress 11 Kosmos 1213 Gran' No.17L Kosmos 1214 Kosmos 1215 Kosmos 1216 Kosmos 1218 Soyuz T-3 Kosmos 1217 OPS 6294 Kosmos 1219 Kosmos 1220 Kosmos 1221 SBS 1 Molniya 1-48 Kosmos 1222 Kosmos 1224 Kosmos 1225 Intelsat V F-2 OPS 3255 (SSU-1, SSU-2, SSU-3) LIPS-1 Kosmos 1226 OPS 5805 Kosmos 1227 Kosmos 1228 Kosmos 1229 Kosmos 1230 Kosmos 1231 Kosmos 1232 Kosmos 1233 Kosmos 1234 Kosmos 1235 Prognoz 8 Ekran No.20L Kosmos 1236
Payloads are separated by bullets ( · ), launches by pipes ( \| ). Crewed flights are indicated in underline. Uncatalogued launch failures are listed in italics. Payloads deployed from other spacecraft are denoted in (brackets).

← 1979

Orbital launches in 1980

1981 →

Kosmos 1149
Molniya 1-46
OPS 6293
Kosmos 1150
Kosmos 1151
Kosmos 1152
Kosmos 1153
Kosmos 1154
Kosmos 1155
OPS 2581
OPS 5117
Kosmos 1156
Kosmos 1157
Kosmos 1158
Kosmos 1159
Kosmos 1160
Kosmos 1161
Kosmos 1162
Kosmos 1163
Kosmos 1164
SolarMax
Tansei-4
Gran' No.16L
Kosmos 1165
Ayame-2
OPS 7245 (SSU-1, SSU-2, SSU-3)
Kosmos 1166
Kosmos 1167
Kosmos 1168
Kosmos 1169
Progress 8
Kosmos 1170
Kosmos 1171
Soyuz 35
Kosmos 1172
Kosmos 1173
Kosmos 1174
Kosmos 1175
OPS 5118
Progress 9
Kosmos 1176
Kosmos 1177
Kosmos 1178
Kosmos 1179
Kosmos 1180
Kosmos 1181
Kosmos 1182
CAT-2
Firewheel
FIRE B
FIRE C
FIRE D
FIRE E
Amsat-P3A
Soyuz 36
Kosmos 1183
NOAA-B
Kosmos 1184
Soyuz T-2
Kosmos 1185
Kosmos 1186
Kosmos 1187
Gorizont No.15L
Kosmos 1188
Meteor-Priroda No.3-1
OPS 3123
Molniya 1-47
Kosmos 1189
Progress 10
Kosmos 1190
Kosmos 1191
Kosmos 1192
Kosmos 1193
Kosmos 1194
Kosmos 1195
Kosmos 1196
Kosmos 1197
Kosmos 1198
Kosmos 1199
Kosmos 1200
Ekran No.19L
DMSP-5D1 F5
Kosmos 1201
Rohini RS-1B
Molniya 3-13
Soyuz 37
Kosmos 1202
Kosmos 1203
Kosmos 1204
Kosmos 1205
Kosmos 1206
Kosmos 1207
Kosmos 1208
- Meteor 2-06
GOES 4
Soyuz 38
Kosmos 1210
Kosmos 1211
Kosmos 1212
Progress 11
Kosmos 1213
Gran' No.17L
Kosmos 1214
Kosmos 1215
Kosmos 1216
Kosmos 1218
Soyuz T-3
Kosmos 1217
OPS 6294
Kosmos 1219
Kosmos 1220
Kosmos 1221
SBS 1
Molniya 1-48
Kosmos 1222
Kosmos 1224
Kosmos 1225
Intelsat V F-2
OPS 3255 (SSU-1, SSU-2, SSU-3)
LIPS-1
Kosmos 1226
OPS 5805
Kosmos 1227
Kosmos 1228
Kosmos 1229
Kosmos 1230
Kosmos 1231
Kosmos 1232
Kosmos 1233
Kosmos 1234
Kosmos 1235
Prognoz 8
Ekran No.20L
Kosmos 1236

Payloads are separated by bullets ( · ), launches by pipes ( | ). Crewed flights are indicated in underline. Uncatalogued launch failures are listed in italics. Payloads deployed from other spacecraft are denoted in (brackets).