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(Top) 1 Mission 2 Telecommunications 3 Instruments 3.1 All-Sky Monitor (ASM) 3.2 High Energy X-ray Timing Experiment (HEXTE) 3.3 Proportional Counter Array (PCA) 4 Results 5 Atmospheric entry 6 See also 7 References 8 External links

Rossi X-ray Timing Explorer

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Rossi X-ray Timing Explorer satellite

Names

Explorer 69
RXTE
XTE

Mission type

Operator

23757

Website

RXTE home page

Mission duration

16 years (achieved)

Spacecraft properties

Spacecraft

Explorer LXVIX

Spacecraft type

Rossi X-ray Timing Explorer

Bus

X-ray Timing Explorer

Manufacturer

Goddard Space Flight Center

Launch mass

3,200 kg (7,100 lb)

Power

800 watts

Start of mission

Launch date

30 December 1995, 13:48:00 UTC

Rocket

Delta II 7920-10 (Delta 230)

Launch site

Cape Canaveral, SLC-17A

Contractor

McDonnell Douglas Astronautics Company

Entered service

30 December 1995

End of mission

Deactivated

12 January 2012

Decay date

30 April 2018 ^[1]

Orbital parameters

Reference system

Regime

409 km (254 mi)

409 km (254 mi)

28.50°

92.60 minutes

Instruments

ASM	All Sky Monitor (ASM)
HEXTE	High-Energy X-ray Timing Experiment (HEXTE)
PCA	Proportional Counter Array (PCA)

Explorer program

← Solar Anomalous and Magnetospheric Particle Explorer (Explorer 68)

Fast Auroral SnapshoT Explorer (Explorer 70) →

The Rossi X-ray Timing Explorer (RXTE) was a NASA satellite that observed the time variation of astronomical X-ray sources, named after physicist Bruno Rossi. The RXTE had three instruments — an All Sky Monitor, the High-Energy X-ray Timing Experiment (HEXTE) and the Proportional Counter Array. The RXTE observed X-rays from black holes, neutron stars, X-ray pulsars and X-ray bursts. It was funded as part of the Explorer program, and was also called Explorer 69.

RXTE had a mass of 3,200 kg (7,100 lb) and was launched from Cape Canaveral on 30 December 1995, at 13:48:00 UTC, on a Delta II launch vehicle. Its International Designator is 1995-074A.^[3]

Mission[edit]

The X-Ray Timing Explorer (XTE) mission has the primary objective to study the temporal and broad-band spectral phenomena associated with stellar and galactic systems containing compact objects in the energy range 2--200 KeV, and in time scales from microseconds to years. The scientific instruments consists of two pointed instruments, the Proportional Counter Array (PCA) and the High-Energy X-ray Timing Experiment (HEXTE), and the All Sky Monitor (ASM), which scans over 70% of the sky each orbit. All of the XTE observing time were available to the international scientific community through a peer review of submitted proposals. XTE used a new spacecraft design that allows flexible operations through rapid pointing, high data rates, and nearly continuous receipt of data at the Science Operations Center (SOC) at Goddard Space Flight Center via a Multiple Access link to the Tracking and Data Relay Satellite System (TDRSS). XTE was highly maneuverable with a slew rate of greater than 6° per minute. The PCA/HEXTE could be pointed anywhere in the sky to an accuracy of less than 0.1°, with an aspect knowledge of around 1 arcminute. Rotatable solar panels enable anti-sunward pointing to coordinate with ground-based night-time observations. Two pointable high gain antennas maintain nearly continuous communication with the TDRSS. This, together with 1 GB (approximately four orbits) of on-board solid-state data storage, give added flexibility in scheduling observations.^[3]

Telecommunications[edit]

Required continuous TDRSS Multiple Access (MA) return link coverage except for zone of exclusion: Real time and playback of engineering/housekeeping data at 16 or 32 kbs - Playback of science data at 48 or 64 kbs.^[4]
Requires 20 minutes of SSA contacts with alternating TDRSS per orbit: Real time and playback of engineering/housekeeping data at 32 kbs - Playback of science data at 512 or 1024 kbs.
For launch and contingency, required TDRSS MA/SSA real time engineering and housekeeping at 1 kbs.
The bit error rate shall be less than 1 in 10E8 for at least 95% of the orbits.

Instruments[edit]

XTE launch

RXTE preparations in 1995

All-Sky Monitor (ASM)[edit]

The All-Sky Monitor (ASM) provided all-sky X-ray coverage, to a sensitivity of a few percent of the Crab Nebula intensity in one day, in order to provide both flare alarms and long-term intensity records of celestial X-ray sources.^[5] The ASM consisted of three wide-angle shadow cameras equipped with proportional counters with a total collecting area of 90 cm² (14 sq in). The instrumental properties were:^[6]^[7]

Energy range: 2–12-keV
Time resolution: observes 80% of the sky every 90 minutes
Spatial resolution: 3' × 15'
Number of shadow cameras: 3, each with 6° × 90° FoV
Collecting area: 90 cm² (14 sq in)
Detector: Xenon proportional counter, position-sensitive
Sensitivity: 30 mCrab

It was built by the CSR at Massachusetts Institute of Technology. The principal investigator was Dr. Hale Bradt.

High Energy X-ray Timing Experiment (HEXTE)[edit]

The High-Energy X-ray Timing Experiment (HEXTE) is a scintillator array for the study of temporal and temporal/spectral effects of the hard X-ray (20 to 200 keV) emission from galactic and extragalactic sources.^[8] The HEXTE consisted of two clusters each containing four phoswich scintillation detectors. Each cluster could "rock" (beamswitch) along mutually orthogonal directions to provide background measurements 1.5° or 3.0° away from the source every 16 to 128 seconds. In addition, the input was sampled at 8 microseconds so as to detect time varying phenomena. Automatic gain control was provided by using an ²⁴¹
Am
radioactive source mounted in each detector's field of view. The HEXTE's basic properties were:^[9]

Energy range: 15–250-keV
Energy resolution: 15% at 60-keV
Time sampling: 8 microseconds
Field of view: 1° FWHM
Detectors: 2 clusters of 4 NaI/CsI scintillation counters
Collecting area: 2 × 800 cm² (120 sq in)
Sensitivity: 1-Crab = 360 count/second per HEXTE cluster
Background: 50 count/second per HEXTE cluster

The HEXTE was designed and built by the Center for Astrophysics & Space Sciences (CASS) at the University of California, San Diego. The HEXTE principal investigator was Dr. Richard E. Rothschild.

Proportional Counter Array (PCA)[edit]

The Proportional Counter Array (PCA) provides approximately 6,500 cm² (1,010 sq in) of X-ray detector area, in the energy range 2 to 60 keV, for the study of temporal/spectral effects in the X-ray emission from galactic and extragalactic sources.^[10] The PCA was an array of five proportional counters with a total collecting area of 6,500 cm² (1,010 sq in). The instrumental properties were:^[11]

Energy range: 2–60-keV
Energy resolution: <18% at 6-keV
Time resolution: 1-μs
Spatial resolution: collimator with 1° Full width at half maximum (FWHM)
Detectors: 5 proportional counters
Collecting area: 6,500 cm² (1,010 sq in)
Layers: 1 propane veto; 3 Xenon, each split into two; 1 Xenon veto layer
Sensitivity: 0.1-mCrab
Background: 90-mCrab

The PCA is being built by the Laboratory for High Energy Astrophysics (LHEA) at Goddard Space Flight Center. The principal investigator was Dr. Jean H. Swank.^[11]

Results[edit]

Observations from the Rossi X-ray Timing Explorer have been used as evidence for the existence of the frame-dragging effect predicted by the theory of general relativityofEinstein. RXTE results have, as of late 2007, been used in more than 1400 scientific papers.

In January 2006, it was announced that Rossi had been used to locate a candidate intermediate-mass black hole named M82 X-1.^[12] In February 2006, data from RXTE was used to prove that the diffuse background X-ray glow in our galaxy comes from innumerable, previously undetected white dwarfs and from other stars' coronae.^[13] In April 2008, RXTE data was used to infer the size of the smallest known black hole.^[14]

RXTE ceased science operations on 12 January 2012.^[15]

Atmospheric entry[edit]

NASA scientists said that the decommissioned RXTE would re-enter the Earth's atmosphere "between 2014 and 2023".^[16] Later, it became clear that the satellite would re-enter in late April or early May 2018,^[17] and the spacecraft fell out of orbit on 30 April 2018.^[18]