Editing Mars Observer

{{short description|Failed NASA orbiter mission to Mars (1992–1993)}}
{{Use mdy dates|date=August 2018}}
{{italic title}}
{{Infobox spaceflight
| name                  = Mars Observer
| names_list            = Mars Geoscience and Climatology Orbiter
| image                 = Mars Observer.jpg
| image_size            = 300px
| image_caption         = Artist rendering of ''Mars Observer'' in orbit around Mars

| mission_type          = [[Mars]] orbiter
| operator              = [[NASA]] / [[JPL]]
| website               = [https://science.nasa.gov/mission/mars-observer/ science.nasa.gov]
| COSPAR_ID             = 1992-063A
| SATCAT                = 22136
| mission_duration      = {{time interval|25 Sept 1992|21 Aug 1993|show=dhm}}<br/><small>Mission failure</small>

| spacecraft_type       =
| spacecraft_bus        = Mars Observer bus (AS-4000-TIROS/DMSP hybrid)
| manufacturer          = [[General Electric]]<br>Astro Space
| dry_mass              = 
| launch_mass           = {{cvt|1018|kg|lb}}
| power                 = 1,147&nbsp;watts

| launch_date           = {{start date text|September 25, 1992, 17:05:01|timezone=yes}}&nbsp;UTC
| launch_rocket         = {{nowrap|[[Commercial Titan III]]/[[Transfer Orbit Stage|TOS]]}}
| launch_site           = [[Cape Canaveral Space Force Station|Cape Canaveral]] [[Cape Canaveral Air Force Station Space Launch Complex 40|LC-40]]
| launch_contractor     = [[Martin Marietta]]

| last_contact          = {{end date text|August 21, 1993, 01:00|timezone=yes}}&nbsp;UTC

| orbit_epoch           = December 6, 1993<br><small>Planned</small>
| orbit_reference       = [[Areocentric orbit|Areocentric]]
| orbit_inclination     = 92.869°
| orbit_semimajor       = {{cvt|3766.159|km|mi}}
| orbit_eccentricity    = 0.004049
| apsis                 = areion

|interplanetary         = 
 {{Infobox spaceflight/IP
   |type                = flyby
   |note                = failed insertion
   |object              = [[Mars]]
   |arrival_date        = August 24, 1993
 }}

| programme             = '''[[Planetary Observer program]]'''
}}
The '''''Mars Observer''''' spacecraft, also known as the '''''Mars Geoscience/Climatology Orbiter''''', was a [[Robotic spacecraft|robotic]] [[space probe]] launched by [[NASA]] on September 25, 1992, to study the Martian surface, atmosphere, climate and magnetic field.  On August 21, 1993, during the interplanetary cruise phase, communication with the spacecraft was lost, three days prior to the probe's [[orbital insertion]].  Attempts to re-establish communications with the spacecraft were unsuccessful.

== Mission background ==

=== History ===
In 1984, a high priority mission to Mars was set forth by the Solar System Exploration Committee.  Then titled the ''Mars Geoscience/Climatology Orbiter'', the Martian [[orbiter]] was planned to expand on the information already gathered by the [[Viking program]]. Preliminary mission goals expected the probe to provide planetary magnetic field data, detection of certain [[spectral line]] signatures of minerals on the surface, images of the surface at 1 [[meter]]/[[pixel]] and global elevation data.<ref name=scinews1/>

''Mars Observer'' was originally planned to be launched in 1990 by a [[Space Shuttle]] Orbiter.  The possibility for an expendable rocket to be used was also suggested, if the spacecraft was designed to meet certain constraints.<ref name=scinews1/> On March 12, 1987, the mission was rescheduled for launch in 1992, in lieu of other backlogged missions (''[[Galileo (spacecraft)|Galileo]]'', [[Magellan probe|Magellan]], ''[[Ulysses (spacecraft)|Ulysses]]'') after the [[Space Shuttle Challenger disaster|Space Shuttle ''Challenger'' disaster]].<ref name=science1/> Along with a launch delay, [[cost overrun|budget overruns]] necessitated the elimination of two instruments to meet the 1992 planned launch<!--what were they?, VIMS and?-->.{{r|Return|scinews2}} As the development matured, the primary science objectives were finalized as:{{r|Return|Astronautix|MOObjectives}}
*Determine the global elemental and mineralogical character of the surface material.
*Define globally the [[topography]] and gravitational field.
*Establish the nature of the Martian [[magnetic field]].
*Determine the temporal and spatial distribution, abundance, sources, and sinks of volatiles and dust over a seasonal cycle.
*Explore the structure and circulation of the [[celestial body's atmosphere|atmosphere]].

The program's total cost is estimated at $813 million.<ref name=NSSDC/>

=== Spacecraft design ===

The ''Mars Observer'' spacecraft had a mass of {{convert|1018|kg|lb}}. Its [[Satellite bus|bus]] measured 1.1 meters tall, 2.2 meters wide, and 1.6 meters deep. The spacecraft was based on previous satellite designs, originally intended and developed to orbit Earth. The RCA AS-4000 Ku-band satellite design was used extensively for the spacecraft bus, propulsion, thermal protection, and solar array. RCA [[Television Infrared Observation Satellite|TIROS]] and [[Defense Meteorological Satellite Program|DMSP Block 50-2]] satellite designs were also utilized in the implementing the Attitude and Articulation Control System (AACS), command and data handling subsystem, and power subsystem, into ''Mars Observer''. Other elements such as the bipropellant components and high-gain antenna were designed specifically for the mission.{{r|MOSafetyReview|NSSDC|MOLaunchPressKit}}

==== Attitude control and propulsion ====
:The spacecraft was [[3-axis stabilized spacecraft|three-axis stabilized]] with four [[reaction wheel]]s and twenty-four [[reaction engine|thrusters]] with 1,346 kilograms of propellant. The propulsion system was a  high thrust, monomethyl hydrazine/nitrogen tetroxide bipropellant system for larger maneuvers and a lower thrust [[hydrazine]] [[monopropellant rocket|monopropellant]] system for minor orbital corrections during the mission. Of the bipropellant thrusters, four located on the aft, provide 490 [[Newton (unit)|newtons]] of thrust for course corrections, control of the spacecraft during the Mars orbital insertion maneuver and large orbit corrections during the mission; another four, located on along the sides of the spacecraft, provide 22&nbsp;newtons for controlling roll maneuvers. Of the hydrazine thrusters, eight provide 4.5&nbsp;newtons to control orbit trim maneuvers; another eight provide 0.9&nbsp;newtons for offsetting, or "desaturating", the reaction wheels. To determine the orientation of the spacecraft, a [[Astrionics#Earth Horizon Sensor|horizon sensor]], a 6-slit star scanner, and five [[Sun sensor]]s were included.{{r|MOSafetyReview|MOLaunchPressKit}}

==== Communications ====
[[File:Mars Observer - HGA diagram.png|thumb|150px|alt=Proposed antenna configuration for combine X/Ka operation (1986)|Proposed X/Ka band antenna (1986)]]
:For telecommunications, the spacecraft included a two-axis [[gimbal]]ed 1.5 meter, parabolic [[high-gain antenna]], mounted to a 6 meter boom to communicate with the [[Deep Space Network]] across the [[X-band]] using two GFP NASA X-band transponders (NXTs) and two GFP command detector units (CDUs). An assembly of six low-gain antennas, and a single medium-gain antenna were also included, to be used during the cruise phase while the high-gain antenna remained stowed, and for contingency measures should communications through the high-gain antenna become restricted. When broadcasting to the Deep Space Network, a maximum of 10.66 kilobytes/second could be achieved while the spacecraft could receive commands at a maximum bandwidth of 62.5 bytes per second.{{r|Astronautix|MOSafetyReview|NSSDC|MOLaunchPressKit}}

:There was also a research payload, the Mars Observer Ka-Band Link Experiment (KABLE), designed to measure performance for possible future missions at Ka-band. It was very low power, intended only for measurements and not operational use.<ref>{{cite web |url=https://tda.jpl.nasa.gov/progress_report/42-88/88S.PDF |title=A K-a band (32 GHz) Beacon Link Experiment (KABLE) With Mars Observer |year=1986}} Proposal.</ref><ref>{{cite web |url=https://core.ac.uk/download/pdf/42785642.pdf |title=The Mars Observer Ka-Band Link Experiment |year=1994}} Final report.</ref>

==== Power ====
:Power was supplied to the spacecraft through a six-panel [[photovoltaic array|solar array]], measuring 7.0&nbsp;meters wide and 3.7&nbsp;meters tall, and would provide an average of 1,147&nbsp;watts when in orbit. To power the spacecraft while [[occultation|occluded]] from the Sun, two 42&nbsp;A·h [[Nickel-cadmium battery|nickel-cadmium batteries]] were included; the batteries would recharge as the solar array received sunlight.{{r|Astronautix|MOSafetyReview|NSSDC|MOLaunchPressKit}}

==== Computer ====
:The computing system on the spacecraft was a retooling of the system used on the TIROS and DMSP satellites. The semiautonomous system was able to store up to 2,000 commands in the included 64 kilobytes of [[random-access memory]], and execute them at a maximum rate of 12.5 commands/second; commands could also provide sufficient autonomous operation of the spacecraft for up to sixty days. To record data, redundant digital tape recorders (DTR) were included and each capable of storing up to 187.5 megabytes, for later playback to the Deep Space Network.<ref name=MOSafetyReview/>

==== Scientific instruments ====
{|
| colspan="2" style="background: #e5e5e5"  | [[Mars Orbiter Camera|Mars Observer Camera]] ('''MOC''')
|-
| [[File:Mars Observer - MOC2 cb.jpg|150px]] <br />'''-'''[[:File:Mars Observer - MOC Diagram.png|see diagram]]
|
{| style="float: right;" class="collapsible collapsed" width="300px"
|-
! style="background: #f2f2f2" | Objectives<ref name=MOObjectives/>
|-
|
*Obtain global synoptic views of the Martian atmosphere and surface to study meteorological, climatological, and related surface changes.
*Monitor surface and atmosphere features at moderate resolution for changes on time scales of hours, days, weeks, months and years.
*Systematically examine local areas at extremely high spatial resolution in order to quantify surface/atmosphere interactions and geological processes.
|}
Consists of narrow-angle and wide-angle telescopic cameras to study the meteorology/climatology and geoscience of Mars.<ref name=NSSDCMOC/>
*{{small|'''Principal investigator:''' Michael Malin / Arizona State University ([http://www.msss.com/all_projects/mars-observer-moc.php website])}}
*{{small|reincorporated on '''[[Mars Global Surveyor]]'''}}
|-
|
|
----
|-
| colspan="2" style="background: #e5e5e5"  | [[Mars Orbiter Laser Altimeter|Mars Observer Laser Altimeter]] ('''MOLA''')
|-
| [[File:Mars Observer - MOLAincolor.jpg|150px]] <br />'''-'''[[:File:Mars Observer - MOLA Diagram.png|see diagram]]
|
{| style="float: right;" class="collapsible collapsed" width="300px"
! style="background: #f2f2f2" | Objectives<ref name=MOObjectives/>
|-
|
* Provide topographic height measurements with a vertical resolution better than 0.5% of the elevation change within the footprint.
* Provide RMS slope information over the footprint.
* Provide surface brightness temperatures at 13.6&nbsp;GHz with a precision of better than 2.5K.
* Provide well sampled radar return wave forms for precise range corrections and the characterization of surface properties.
|}
A [[Laser ranging#Physics and astronomy|laser altimeter]] used to define the [[topography]] of [[Mars]].<ref name=NSSDCMOLA/>
*{{small|'''Principal investigator:''' David Smith / NASA Goddard Space Flight Center}}
*{{small|reincorporated on '''[[Mars Global Surveyor]]'''}}
|-
|
|
----
|-
| colspan="2" style="background: #e5e5e5"  | [[Thermal Emission Spectrometer]] ('''TES''')
|-
| [[File:Mars Observer - MGSTESpic sm.gif|150px]] <br />'''-'''[[:File:Mars Observer - TES Diagram.png|see diagram]]
|
{| style="float: right;" class="collapsible collapsed" width="300px"
! style="background: #f2f2f2" | Objectives<ref name=MOObjectives/>
|-
|
* Determine and map the composition of surface minerals, rocks and ice.
* Study the composition, particle size, and spatial and tempora distribution of atmospheric dust.
* Locate water-ice and carbon dioxide condensate clouds and determine their temperature, height and condensate abundance.
* Study the growth, retreat and total energy balance of the polar cap deposits.
* Measure the thermophysical properties of the Martian surface (thermal inertia, albedo) used to derive surface particle size and rock abundance.
* Determine atmospheric temperature, pressure, water vapor, and ozone profiles, and seasonal pressure variations.
|}
Uses three sensors (Michelson interferometer, solar reflectance sensor, broadband radiance sensor) to measure thermal infrared emissions to map the mineral content of surface rocks, frosts and the composition of clouds.<ref name=NSSDCTES/>
*{{small|'''Principal investigator:''' Philip Christensen / Arizona State University}}
*{{small|reincorporated on '''[[Mars Global Surveyor]]'''}}
|-
|
|
----
|-
| colspan="2" style="background: #e5e5e5"  | Pressure Modulator Infrared Radiometer ('''PMIRR''')
|-
| [[File:Mars Observer - PMIRR Diagram.png|150px]]
|
{| style="float: right;" class="collapsible collapsed" width="300px"
! style="background: #f2f2f2" | Objectives<ref name=MOObjectives/>
|-
|
* Map the three-dimensional and time-varying thermal structure of the atmosphere from the surface to 80&nbsp;km altitude.
* Map the atmospheric dust loading and its global, vertical and temporal variation.
* Map the seasonal and spatial variation of the vertical distribution of atmospheric water vapor to an altitude of at least 35&nbsp;km.
* Distinguish between atmospheric condensates and map their spatial and temporal variation.
* Map the seasonal and spatial variability of atmospheric pressure.
* Monitor the polar radiation balance.
|}
Uses narrow-band radiometric channels and two pressure modulation cells to measure atmospheric and surface emissions in the thermal infrared and a visible channel to measure dust particles and condensates in the atmosphere and on the surface at varying longitudes and seasons.<ref name=NSSDCPMIRR/>
*{{small|'''Principal investigator:''' Daniel McCleese / JPL}}
*{{small|reincorporated on '''[[Mars Climate Orbiter]]''' and then further developed and flown on '''[[Mars Reconnaissance Orbiter]]'''}}
|-
|
|
----
|-
| colspan="2" style="background: #e5e5e5"  | Gamma Ray Spectrometer ('''GRS''')
|-
| [[File:Mars Observer - GRS.png|150px]] <br />'''-'''[[:File:Mars Observer - GRS Diagram.png|see diagram]]
|
{| style="float: right;" class="collapsible collapsed" width="300px"
! style="background: #f2f2f2" | Objectives<ref name=MOObjectives/>
|-
|
* Determine the elemental composition of the surface of Mars with a spatial resolution of a few hundred kilometers through measurements of incident gamma-rays and albedo neutrons ([[Hydrogen|H]], [[Oxygen|0]], [[Magnesium|Mg]], [[Aluminum|Al]], [[Silicon|Si]], [[Sulfur|S]], [[Chlorine|Cl]], [[Potassium|K]], [[Iron|Fe]], [[Thorium|Th]], [[Uranium|U]]).
* Determine hydrogen depth dependence in the top tens of centimeters.
* Determine the atmospheric column density.
* Determine the arrival time and spectra of gamma-ray bursts.
|}
Records the spectrum of [[gamma rays]] and [[neutron]]s emitted by the radioactive decay of [[Chemical element|elements]] contained in the Martian surface.<ref name=NSSDCGRS/>
*{{small|'''Principal investigator:''' William Boynton / University of Arizona / NASA Goddard Space Flight Center ([http://heasarc.gsfc.nasa.gov/docs/heasarc/missions/marsobs.html#instrumentation HEASARC website])}}
*{{small|reincorporated on '''[[2001 Mars Odyssey]]'''}}
|-
|
|
----
|-
| colspan="2" style="background: #e5e5e5"  | [[Magnetometer]] and Electron Reflectometer ('''MAG'''/'''ER''')
|-
| [[File:Mars Observer - ER.gif|150px]]
|
{| style="float: right;" class="collapsible collapsed" width="300px"
! style="background: #f2f2f2" | Objectives<ref name=MOObjectives/>
|-
|
* Establish the nature of the magnetic field of Mars.
* Develop models for its representation, which take into account the internal sources of magnetism and the effects of the interaction with the solar wind.
* Map the Martian crustal remanlint field using the fluxgate sensors and extend these in-situ measurements with the remote capability of the electron-reflectometer sensor.
* Characterize the solar wind/Mars plasma interaction.
* Remotely sense the Martian ionosphere.
|}
Uses the components of the on-board telecommunications system and the stations of the [[Deep Space Network]] to collect data on the nature of the [[magnetic field]] and interactions the field may have with [[solar wind]].<ref name=NSSDCMAGER/>
*{{small|'''Principal investigator:''' Mario Acuna / NASA Goddard Space Flight Center}}
*{{small|reincorporated on '''[[Mars Global Surveyor]]'''}}
|-
|
|
----
|-
| colspan="2" style="background: #e5e5e5"  | Radio Science experiment ('''RS''')
|-
| [[File:Mars Observer - RS Diagram.png|150px]]
|
{| style="float: right;" class="collapsible collapsed" width="300px"
! style="background: #f2f2f2" | Objectives<ref name=MOObjectives/>
|-
| '''Atmosphere'''
* Determine profiles of refractive index, number density, temperature, and pressure at the natural experimental resolution (approx. 200&nbsp;m) for the lowest few scale heights at high latitudes in both hemispheres on a daily basis.
* Monitor both short term and seasonal variation in atmospheric stratification.
* Characterize the thermal response of the atmosphere to dust loading.
* Explore the thermal structure of the boundary layer at high vertical resolution (approx. 10&nbsp;m).
* Determine the height and peak plasma density of the daytime ionosphere.
* Characterize the small scale structure of the atmosphere and ionosphere.
|-
| '''Gravity'''
* Develop a global, high-resolution model for the gravitational field.
* Determine both local and broad scale density structure and stress state of the Martian crust and upper mantle.
* Detect and measure temporal changes in low degree harmonics of the gravitational field.
|}
Collects data on the [[gravity field]] and the [[Martian atmosphere|Martian atmospheric structure]] with a special emphasis on temporal changes near the polar regions.<ref name=NSSDCRS/>
*{{small|'''Principal investigator:''' G. Tyler / Stanford University}}
*{{small|reincorporated on '''[[Mars Global Surveyor]]'''}}
|-
|
|
----
|-
| colspan="2" style="background: #e5e5e5"  | Mars Balloon Relay ('''MBR''')
|-
| <!--[[File:|150px]]-->
|
Planned as augmentation to return data from the penetrators and surface stations of the Russian Mars '94 mission and from penetrators, surface stations, a rover, and a balloon from the [[Mars 96|Mars '96]] mission.<ref name=NSSDCMBR/>
*{{small|'''Principal investigator:''' Jacques Blamont / Centre National de la Recherche Scientifique}}
*{{small|reincorporated on '''[[Mars Global Surveyor]]'''}}
|-
|
|
----
|-
|}<ref name=Astronautix/><ref name=NSSDC/>

{{Gallery|align=center|title=Images of the spacecraft |width=175 |File:Mars Observer - spacecraft diagram -rev2.png|alt1=Labeled diagram of Mars Observer |{{small|Labeled diagram of ''Mars Observer''.}}
|File:Mars Observer preparations.jpg|alt2=Mars Observer in the Payload Hazardous Servicing Facility |{{small|''Mars Observer'' in the Payload Hazardous Servicing Facility.}}
|File:Mars Observer - marsobs 2.png|alt3=Technician assembling the Mars Observer space probe |{{small|Technician assembling the ''Mars Observer'' space probe.}}
|File:Mars - Observermarsobs 3.png|alt4=Mars Observer in the clean room |{{small|''Mars Observer'' in the clean room.}}
}}

== Mission profile ==
{| style="float: right;"
! colspan="2" | Timeline of operations
|-
|
{| cellspacing="0" cellpadding="0" align="center" width="100%" style="border:0px solid #e6e6e6"
|-
| colspan="2" |
----
|-
! scope="col" width="75" | Date
! scope="col" width="350" | Event
|-
| colspan="2" |
----
|-
| {{center|1992-09-25}}
| style="background:#f2f2f2;"| Spacecraft launched at 17:05:01 UTC
|-
| {{center|1993-08-21}}
| style="background:#f2f2f2;"| Communication with spacecraft lost at 01:00 UTC.
|-
| {{center|1993-08-24}}
|
<!--Collapsable data header-->
  {| class="collapsible collapsed" align="center" width="100%"
  ! colspan="2" style="background-color:#f9f9f9;font-weight:normal;" | {{pad|2em}} {{fontcolor|red|Begin Mars orbital insertion maneuvers}}
  |-
  | colspan="2" |
----
  |- style="background-color:#e0e0e0"
  ! scope="col" width="75" | Time
  ! scope="col" width="230" | Event {{pad|6em}}
  |-
  | colspan="2" |
----
<!--Collapsable data input-copy for more entries-->
  |-
  | {{center|'''1993-08-24'''}}
  | {{fontcolor|red|Mars Orbit Insertion maneuver}}
  |-
  | {{center|'''1993-09-04'''}}
  | {{fontcolor|red|Elliptical Change Maneuver-1}}
  |-
  | {{center|'''1993-09-04'''}}
  | {{fontcolor|red|Elliptical Change Maneuver-2}}
  |-
  | {{center|'''1993-09-16'''}}
  | {{fontcolor|red|Elliptical Change Maneuver-3}}
  |-
  | {{center|'''1993-10-17'''}}
  | {{fontcolor|red|Transfer to Low Orbit maneuver-1}}
  |-
  | {{center|'''1993-10-18'''}}
  | {{fontcolor|red|Transfer to Low Orbit maneuver-2}}
  |}
|-
| {{center|1993-09-27}}
| style="background:#f2f2f2;"| Mission declared a loss.  No further attempts to contact.
|-
| {{center|1993-12-17}}
| style="background:#f2f2f2;"| {{fontcolor|red|Begin mapping phase}}
|}
|-
|
{{center|[[:File:Mars Observer - Anticipated timeline.png|{{small|See the anticipated timeline for the ''Mars Observer'' mission.}}]]}}
{{center|{{small|Items in {{fontcolor|red|'''red'''}} were unrealized events.}}}}
|}

=== Launch and trajectory ===
''Mars Observer'' was launched on September 25, 1992, at 17:05:01 UTC by the [[National Aeronautics and Space Administration]] from [[Cape Canaveral Air Force Station Space Launch Complex 40|Space Launch Complex 40]] at the [[Cape Canaveral Air Force Station]] in Florida, aboard a [[Titan III|Commercial Titan III CT-4]] launch vehicle. The complete burn sequence lasted for 34 minutes after a solid-fuel [[Transfer Orbit Stage]]  placed the spacecraft into an 11-month, Mars transfer trajectory, at a final speed of 5.28&nbsp;km/s with respect to Mars.<ref name=MOLaunchPressKit/>

On August 25, 1992, particulate contamination was found within the spacecraft. After a full inspection, a cleaning was determined necessary and was performed on August 29. The suspected cause of the contamination were measures taken to protect the spacecraft prior to the landfall of [[Hurricane Andrew]] which struck the coast of Florida on August 24.{{r|MOLaunchPressKit|trash|launch}}
{{Clear}}
{{Gallery|align=center|width=175 |File:Mars Observer - launch configuration.png|alt1=Diagram of Mars Observer in launch configuration |{{small|Diagram of Mars Observer in launch configuration.}}
|File:Mars Observer launch.png|alt2=Titan III vehicle launching the Mars Observer spacecraft |{{small|[[Titan III]] vehicle launching the ''Mars Observer'' spacecraft.}}
|File:Mars Observer - trajectory2.png|alt3=Diagram of the interplanetary trajectory of Mars Observer |{{small|Diagram of the interplanetary trajectory of ''Mars Observer''.}}
}}

=== Encounter with Mars ===
''Mars Observer'' was scheduled to perform an [[orbital insertion]] maneuver on August 24, 1993, but contact with the spacecraft was lost on August 21, 1993. The likely reason for the spacecraft failure was the leakage of fuel and oxidizer vapors through the improperly designed PTFE check valve to the common pressurization system. During interplanetary cruise, the vapor mix had accumulated in feed lines and pressurant lines, resulting in explosion and their rupture after the engine was restarted for routine course correction. A similar problem later crippled the [[Akatsuki (spacecraft)|Akatsuki]] space probe in 2010. Although none of the primary objectives were achieved, the mission provided interplanetary cruise phase data, collected up to the date of last contact. This data would be useful for subsequent missions to Mars. Science instruments originally developed for ''Mars Observer'' were placed on four subsequent spacecraft to complete the mission objectives: [[Mars Global Surveyor]] launched in 1996, [[Mars Climate Orbiter]] launched in 1998, [[2001 Mars Odyssey]] launched in 2001 and [[Mars Reconnaissance Orbiter]] launched in 2005.<ref name=sep20180821/>

{{Gallery|align=center|width=175 |File:Mars Observer - m1.gif|alt1=First image of Mars taken by MOC on July 27, 1993 |{{small|First image of [[Mars]] taken by ''MOC'' on July 27, 1993.}}
|File:Mars Observer - m2.gif|alt2=Second narrow-angle MOC image of Mars, acquired one hour after the first |{{small|Second ''MOC'' image of Mars, acquired one hour after the first.}}
|File:Mars Observer - wa-mars.gif|alt3=Among the last of the images acquired by Mars Observer and one of few that were color, the image was acquired by the wide-angle camera |{{small|One of few wide-angle images by ''Mars Observer'' that were in color.}}
|File:Mars Observer - jup.gif|alt4=Jupiter as imaged by MOC en route to Mars |{{small|[[Jupiter]] as imaged by ''MOC'' en route to Mars.}}
}}

==== Intended operations ====
[[File:Mars Observer - mapping the martian world mars observer.ogv|299px|thumb|View video]]
{{Main|Exploration of Mars}}
{{multiple image
| footer   = The complement of instruments on Mars Observer would have provided a large amount of information about Mars.
| image1   = Mars Observer - orbit insertion.png
| width1   = 98
| alt1     = Diagram of the orbital insertion maneuver
| caption1 = {{small|Diagram of the orbit insertion}}
| image2   = Mars Observer - mapping phase.png
| width2   = 88
| alt2     = Diagram of the mapping cycle
| caption2 = {{small|Diagram of the mapping cycle}}
| image3   = Mars Observer 2.jpg
| width3   = 97
| alt3     = Artistic depiction of the spacecraft in orbit
| caption3 = {{small|Artistic depiction}}
}}
On August 24, 1993, ''Mars Observer'' would turn 180 degrees and ignite the bipropellant thrusters to slow the spacecraft, entering into a highly elliptical orbit. Over the next three months, subsequent "transfer to lower orbit" (TLO) maneuvers would be performed as the spacecraft reached [[periapsis]], eventually resulting in an approximately circular, 118-minute orbit around Mars.<ref name=MOArrivalPressKit/>

The primary mission was to begin on November 23, 1993, collecting data during one [[Martian year]] (approximately 687 Earth days). The first global map was expected to be completed on December 16, followed by [[solar conjunction]] beginning on December 20, and lasting for nineteen days, ending on January 3, 1994; during this time, mission operations would be suspended as radio contact would not be possible.<ref name=MOArrivalPressKit/>

Orbiting Mars at an approximate speed of 3.4&nbsp;km/s, the spacecraft would travel around Mars in a north to south, polar orbit. As the spacecraft circles the planet, horizon sensors indicate the orientation of the spacecraft while the reaction wheels would maintain the orientation of the instruments, towards Mars. The chosen orbit was also Sun-synchronous, allowing the daylit side of Mars to always be captured during the mid-afternoon of each [[Timekeeping on Mars#Sols|Martian Sol]]. While some instruments could provide a real-time data link when Earth was in view of the spacecraft, data would also be recorded to the digital tape recorders and played back to Earth each day. Over 75&nbsp;[[gigabyte]]s of scientific data was expected to be yielded during the primary mission, much more than any previous mission to Mars. The end of the operable life for the spacecraft was expected to be limited by the supply of propellant and the condition of the batteries.<ref name=MOArrivalPressKit/>
<!--Following the primary mission...-->

== Communications loss ==
{{multiple image
| footer    = Investigators believe oxidizer leaked through check valves and mixed with fuel when pyro-valves 5 and 6 were opened.
| image1    = Mars Observer - loss of telemetry.png
| width1     = 114
| alt1      =
| caption1  = <small>Loss of telemetry</small>
| image2    = Mars Observer - bipropellant system failure diagram.png
| width2     = 86
| alt2      =
| caption2  = <small>Suspected failure</small>
}}
On August 21, 1993, at 01:00 UTC, three days prior to the scheduled [[Mars]] [[orbital insertion]], there was an "inexplicable" loss of contact with ''Mars Observer''.<ref name=commloss/> New commands were sent every 20 minutes in the hopes that the spacecraft had drifted off course and could regain contact. However, the attempt was unsuccessful.<ref name="commloss" /> It is unknown whether the spacecraft was able to follow its automatic programming and go into Mars orbit or if it flew by Mars and is now in a [[heliocentric orbit]].

On January 4, 1994, an independent investigation board from the [[Naval Research Laboratory]], announced their findings: the most probable cause in the loss of communication was a rupture of the fuel pressurization tank in the spacecraft's propulsion system.<ref name=iiboard/> It is believed that [[hypergolic fuel]] may have leaked past valves in the system during the cruise to Mars, allowing the fuel and oxidizer to combine prematurely before reaching the combustion chamber.  The leaking fuel and gas probably resulted in a high spin rate, causing the spacecraft to enter into the "contingency mode"; this interrupted the stored command sequence and did not turn the transmitter on.<ref name=iiboard/> The engine was derived from one belonging to an Earth orbital satellite and was not designed to lie dormant for months before being fired.{{cn|date=September 2024}}

{| class="wikitable" style="margin:1em auto;"
! Quoted from the report<ref name=iiboard/>
|-
| scope="col" width="750" | Because the telemetry transmitted from the Observer had been commanded off and subsequent efforts to locate or communicate with the spacecraft failed, the board was unable to find conclusive evidence pointing to a particular event that caused the loss of the Observer.

However, after conducting extensive analyses, the board reported that the most probable cause of the loss of communications with the spacecraft on August 21, 1993, was a rupture of the fuel (monomethyl hydrazine (MMH)) pressurization side of the spacecraft's propulsion system, resulting in a pressurized leak of both helium gas and liquid MMH under the spacecraft's thermal blanket.  The gas and liquid would most likely have leaked out from under the blanket in an unsymmetrical manner, resulting in a net spin rate.  This high spin rate would cause the spacecraft to enter into the "contingency mode," which interrupted the stored command sequence and thus, did not turn the transmitter on.

Additionally, this high spin rate precluded proper orientation of the solar arrays, resulting in discharge of the batteries.  However, the spin effect may be academic, because the released MMH would likely attack and damage critical electrical circuits within the spacecraft.

The board's study concluded that the propulsion system failure most probably was caused by the inadvertent mixing and the reaction of nitrogen tetroxide (NTO) and MMH within titanium pressurization tubing, during the helium pressurization of the fuel tanks.  This reaction caused the tubing to rupture, resulting in helium and MMH being released from the tubing, thus forcing the spacecraft into a catastrophic spin and also damaging critical electrical circuits.
|}

== Aftermath ==
The [[Mars Exploration Program]] was formed officially in the wake of the Mars Observer's failure in September 1993.<ref name=strategy9520/> The goals of that program include identifying the location of [[Water on Mars|water]], and preparing for crewed missions to Mars.<ref name=strategy9520/>

== See also ==
{{Portal|Spaceflight}}
* [[Exploration of Mars]]
* [[List of missions to Mars]]
* [[Planetary Observer program]]
* [[Space exploration]]
* [[Unmanned space mission]]s

== References ==
{{reflist|refs=

<ref name="Astronautix">{{cite web
| url= http://www.astronautix.com/m/marsobserver.html
| title= Mars Observer
| author1= Mark Wade
| website= Encyclopedia Astronautica 
| access-date= 23 December 2010 }}
</ref>

<ref name="commloss">{{cite news 
| url= https://www.nytimes.com/1993/08/23/us/nasa-loses-communication-with-mars-observer.html
| title= NASA Loses Communication With Mars Observer
| access-date= 17 June 2008
| author1= John Noble Wilford
| date= 23 August 1993
| newspaper= [[The New York Times]] }}
</ref>

<ref name="iiboard">{{cite press release
| url= http://www.msss.com/mars/observer/project/mo_loss/nasa_mo_loss.txt
| title= NASA Mars Observer Failure Board Press Release
| format= Text 
| date= 4 January 1994 }}
</ref>

<ref name="launch">{{cite news
| url= https://www.nytimes.com/1992/09/26/us/us-launches-a-spacecraft-on-a-mars-trip.html
| title= U.S. Launches A Spacecraft On a Mars Trip
| access-date= 21 June 2008
| author1= John Noble Wilford
| date= 26 September 1992
| newspaper= [[The New York Times]] }}
</ref>

<ref name="MOArrivalPressKit">{{cite press release
| publisher= [[NASA]]
| date= August 1993
| format= Text
| title= Mars Observer: Mars Orbit Insertion Press Kit 
| url= http://spacelink.nasa.gov/NASA.Projects/Space.Science/Solar.System/Mars.Observer/Press.Kit.Orbit.Insertion
| access-date= 21 March 2011
| url-status= unfit
| archive-url= https://web.archive.org/web/20040216034435/http://spacelink.nasa.gov/NASA.Projects/Space.Science/Solar.System/Mars.Observer/Press.Kit.Orbit.Insertion 
| archive-date= 16 February 2004 }}
</ref>

<ref name="MOLaunchPressKit">{{cite press release
| publisher= [[NASA]]
| date= September 1992
| format= Text
| title= MARS OBSERVER PRESS KIT
| url= http://spacelink.nasa.gov/NASA.Projects/Space.Science/Solar.System/Mars.Observer/Press.Kit
| access-date= 21 March 2011
| url-status= unfit
| archive-url= https://web.archive.org/web/20040216034435/http://spacelink.nasa.gov/NASA.Projects/Space.Science/Solar.System/Mars.Observer/Press.Kit
| archive-date= 16 February 2004 }}
</ref>

<ref name="MOObjectives">{{cite journal
| author1= Arden L. Albee
| date= 1988
| title= Workshop on Mars Sample Return Science
| pages= 25–29
| publisher= Lunar and Planetary Institute 
| bibcode= 1988msrs.work...25A
| journal= In Lunar and Planetary Institute }}
</ref>

<ref name="MOSafetyReview">{{cite press release
| publisher= RCA Astro-Electronics
| date= 17 November 1986
| title= MARS OBSERVER: PHASE 0 SAFETY REVIEW DATA PACKAGE
| hdl= 2060/19870011586 }}
</ref>

<ref name="NSSDC">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1992-063A
| title= Mars Observer
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 23 December 2010 }}
</ref>

<ref name="NSSDCGRS">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-02
| title= Gamma Ray Spectrometer (GRS)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="NSSDCMAGER">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-03
| title= Magnetometer and Electron Reflectometer (MAG/ER)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="NSSDCMBR">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-08
| title= Mars Balloon Relay (MBR)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="NSSDCMOC">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-07
| title= Mars Observer Camera (MOC)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="NSSDCMOLA">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-04
| title= Mars Observer Laser Altimeter (MOLA)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="NSSDCPMIRR">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-05
| title= Pressure Modulator Infrared Radiometer (PMIRR)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="NSSDCRS">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-01
| title= Radio Science (RS)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="NSSDCTES">{{cite web
| url= https://nssdc.gsfc.nasa.gov/nmc/experiment/display.action?id=1992-063A-06
| title= Thermal Emission Spectrometer (TES)
| website= nssdc.gsfc.nasa.gov
| publisher= [[NASA]]
| access-date= 19 February 2011 }}
</ref>

<ref name="Return">{{cite press release
| publisher= [[Jet Propulsion Laboratory]]
| date= 1 August 1993
| title= Return to the Red Planet: The Mars Observer Mission
| hdl= 2014/27541 }}
</ref>

<ref name="science1">{{cite journal
| author1= M. Mitchell Waldrop
| date= 1987
| title= Company Offers To Buy NASA A Rocket
| journal= [[Science (journal)|Science]]
| volume= 235
| issue= 4796
| pages= 1568
| publisher= [[American Association for the Advancement of Science]] 
| jstor= 1698285
| bibcode= 1987Sci...235.1568W
| doi= 10.1126/science.235.4796.1568a
| pmid= 17795582 }}
</ref>

<ref name="scinews1">{{cite journal
| author1= Jonathon Eberhart
| date= 1986
| title= NASA Sets Sensors for 1990 Return to Mars
| journal= Science News
| volume= 239
| issue= 21
| pages= 330
| publisher= Society for Science & the Public
| jstor= 3970693
| doi= 10.2307/3970693 }}
</ref>

<ref name="scinews2">{{cite journal
| author1= Jonathon Eberhart
| date= 1988
| title= An Act of Discovery: On the Road Again
| journal= Science News
| volume= 134
| issue= 15
| pages= 231
| publisher= Society for Science & the Public
| jstor= 3973010
| doi= 10.2307/3973010 }}
</ref>

<ref name=sep20180821>{{cite web
| url= https://www.saturdayeveningpost.com/2018/08/5000-pound-spacecraft-inexplicably-disappeared/
| title= When a 5,000-Pound Spacecraft Inexplicably Disappeared 
| work= Saturday Evening Post
| author1= Troy Brownfield
| date= 21 August 2018
| access-date= 3 March 2021 }}
</ref>

<ref name=strategy9520>{{cite web
| author1= Donna Shirley
| title= Mars Exploration Program Strategy: 1995–2020
| url= http://trs-new.jpl.nasa.gov/dspace/bitstream/2014/23620/1/96-0064.pdf
| publisher= [[American Institute of Aeronautics and Astronautics]]
| access-date= 18 October 2012
| url-status= dead
| archive-url= https://web.archive.org/web/20130511200249/http://trs-new.jpl.nasa.gov/dspace/bitstream/2014/23620/1/96-0064.pdf
| archive-date= 11 May 2013 }}
</ref>

<ref name="trash">{{cite news
| url= https://www.nytimes.com/1992/08/28/us/mishap-delays-mission-to-mars.html
| title= Mishap Delays Mission to Mars
| access-date= 21 June 2008
| author1= John Noble Wilford
| date= 28 August 1992
| newspaper= [[The New York Times]] }}
</ref>

}}

== External links ==
*[http://www.planetary.brown.edu/planetary/text/MO_presskit.txt Mars Observer launch press kit] {{Webarchive|url=https://web.archive.org/web/20160304124324/http://www.planetary.brown.edu/planetary/text/MO_presskit.txt |date=March 4, 2016 }}
*[https://web.archive.org/web/20150603031843/http://solarsystem.nasa.gov/missions/profile.cfm?MCode=MarsObserver Mars Observer Mission Profile] by [http://solarsystem.nasa.gov/ NASA's Solar System Exploration]
*[https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1992-063A Mars Observer] at NSSDC Master Catalog
*[http://barsoom.msss.com/mars/observer/project/mo_loss/moloss.html The Loss of Mars Observer] at Malin Space Science Systems. {{webarchive |url=https://web.archive.org/web/20100327185512/http://barsoom.msss.com/mars/observer/project/mo_loss/moloss.html |date=March 27, 2010}}
*[https://web.archive.org/web/20150906135140/http://solarsystem.nasa.gov/missions/profile.cfm?Sort=Alpha&Letter=M&Alias=Mars%20Observer NASA – Mars Observer]

{{Mars spacecraft}}
{{Jet Propulsion Laboratory}}
{{Orbital launches in 1992}}

[[Category:NASA space probes]]
[[Category:Derelict satellites in heliocentric orbit]]
[[Category:Missions to Mars]]
[[Category:Spacecraft launched in 1992]]
[[Category:Articles containing video clips]]
[[Category:Space accidents and incidents in the United States]]