ADEOS II

ADEOS II

Artist's impression of ADEOS II
Mission type Environmental monitoring, observation
Operator NASDA
COSPAR ID 2002-056A
SATCAT № 27597
Spacecraft properties
Manufacturer Mitsubishi Electric
Launch mass 3,680 kilograms (8,110 lb)
Power 5000 kW
Start of mission
Launch date 14 December 2002, 01:31:00 (2002-12-14UTC01:31Z) UTC
Rocket H-IIA 202
Launch site Tanegashima Yoshinobu 1
End of mission
Last contact 23 October 2003, 23:49 (2003-10-23UTC23:50Z) UTC
Orbital parameters
Reference system Geocentric
Regime Sun-synchronous
Eccentricity 0.0000295
Perigee 803 kilometres (499 mi)
Apogee 803 kilometres (499 mi)
Inclination 98.2831 degrees
RAAN 313.1320°
Argument of perigee 87.0448°
Mean anomaly 27.5323°
Mean motion 14.26617148
Epoch 24 October 2013 12:31:00 (UTC)[1]
Instruments
AMSR, GLI, ILAS-II, POLDER, SeaWinds

ADEOS II (Advanced Earth Observing Satellite 2) was an Earth observation satellite[2] launched by NASDA, NASA and CNES in December 2002.[3] Its Japanese name was Midori 2,[4] and it was the successor to the 1996 mission ADEOS I. The mission ended in October 2003 after the satellite's solar panels failed.[5]

Mission overview

The three primary objectives of the mission, as identified by NASDA, were to:[6]

  1. Regularly monitor the water and energy cycle as a part of the global climate system
  2. Quantitatively estimate the biomass and fundamental productivity as a part of the carbon cycle
  3. Detect trends in long term climate change as a result of continuing the observations started by ADEOS

The project had a proposed minimum life of three years,[7] with a five-year goal.[8]

Launch

The mission was originally scheduled to launch aboard a H-II rocket in February 2002. This was postponed as the Japanese Space Activities Commission would not launch without having three successful missions aboard the new H-IIA rocket.[9]

The satellite was successfully launched from Tanegashima Space Center pad YLP-1 on 14 December 2002, aboard H-2A-202.[10] Other payloads onboard included the Japanese MicroLabsat and WEOS devices, as well as the Australian FedSat.[4]

Failure

On 23 October 2003, the solar panel failed.[5] At 2349 UTC, the satellite switched to "light load" operation due to an unknown error. This was intended to power down all observation equipment to conserve energy. At 2355 UTC, communications between the satellite and the ground stations ended, with no further telemetry received.[5] Further attempts to procure telemetry data on 24 October (at 0025 and 0205 UTC) also failed.[11]

Investigation

After the power failure, JAXA (NASDA's successor) formed the Midori II anomaly investigation team. Analysis of data received before transmissions ceased showed that the solar panel's power output had decreased from 6 kW to 1 kW.[5] The investigation team began surveying the mission to establish whether the failure was due to a technical malfunction or a solar flare.[5]

One hypothesis was that debris had impacted the satellite's power harness between the solar array and the satellite bus. The harness was a core of wires enclosed in multi-layer insulation. The debris impact was theorised to have caused an electric arc.[2]

The mission officially ended at the end of October 2003, with JAXA conceding that the "possibility of restoring the operations of Midori II [was] extremely slim."[5] The mission, which had cost approximately 70 billion Yen (US$570 million)[4] was only able to recoup an estimated 300 million Yen through insurance.[5]

Instruments

Annotation of ADEOS II and its instruments

The satellite was equipped with five primary instruments Advanced Microwave Scanning Radiometer (AMSR), Global Imager (GLI), Improved Limb Atmospheric Spectrometer-II (ILAS-II), Polarization and Directionality of the Earth's Reflectances (POLDER), and SeaWinds. These instruments were designed to monitor Earth's water cycle, study biomass in the carbon cycle, and detect trends in long-term climate change.[7] The mission was established to continue the work undertaken by ADEOS I between 1996 and 1997.[7][12]

Subsystems

In addition to the five main instruments, nine avionic subsystems were allocated to the bus module.[2] These were the Communication and Data-Handling Subsystem (C&DH), Inter-Orbit Communication Subsystem (IOCS), Mission Data Processing Subsystem (MDPS), Optical Data Recorder (ODR), Electrical Power Subsystem (EPS), Paddle Subsystem (PDL), Attitude and Orbit Control Subsystem (AOCS), Reaction Control Subsystem (RCS), and the Direct Transmission Subsystem (DTL).[2]

The C&DH subsystem received and decoded the satellite's tracking control command signals and acted as a processing interface between the instruments. It was capable of adjusting settings on the instruments such as temperature and voltage. The IOCS was used to communicate with data relay satellites (see Data transfer).[2]

The MDP device formatted mission data to be sent via the IOCS, and would process it into a data packet.[2] The ODR was a large-volume storage device that used an optical magnetic disk system.[2] The EPS provided power to the satellite's subsystems. The PDL managed the satellite's solar panel, and transferred electrical energy to the EPS. The solar panel was capable of generating 5 kW using 55,680 cells on a jointed mast.[2]

The AOCS was used to establish the attitude control following the satellite's deployment from the rocket. It was subsequently used to adjust the satellite's attitude, orbit, and solar paddle. The AOCS was equipped with a number of attitude sensors, including a control-standard unit (IRC), an Earth sensor (ESA), and a fine sun sensor assembly (FSSA).[2]

The RCS was used to generate propulsion power for attitude adjustments after deployment and control orbit using data from the AOCS.[2]

Data transfer

ADEOS II transferred data to and from Artemis and the Data Relay Test Satellite (DRTS). The Artemis connection transferred information over a 26 GHz Ka band link (for payload data) and a 2 GHz S band link (for telemetry, tracking and control data).[2]

These signals were then downlinked to the Earth Observation Center (EOC) via feeder link stations and the Redu Station.[2] ADEOS II also sent mission data directly to NASA stations, which routed information to bodies such as the EOC and sensor-providing organisations.[2]

Footnotes

Sources

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