Image:LISA-waves.jpg
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[edit] Summary
NASA illustration of LISA, taken from http://lisa.jpl.nasa.gov/gallery/lisa-waves.html. High resolution TIFF compressed with "cjpeg" from libjpeg-progs.
NASA's description:
The three LISA spacecraft will be placed in orbits that form a triangular formation with center 20° behind the Earth and side length 5 million km. (The figure showing the formation is not to scale.)
Each spacecraft will be in an individual Earth-like orbit around the Sun. The orbits are chosen to minimize changes in the lengths of the sides of the triangle. The orbits of the three spacecraft have a relationship between inclination and eccentricity that inclines the plane of the formation by 60° with respect to the ecliptic. The nodal longitudes of the three orbits are shifted by 120° to create the triangle. The heliocentric orbit offers a particularly quiet environment, critical for the control of disturbances on the test masses defining the interferometer arms. The test masses are free-falling and shielded by the enclosing spacecraft from disturbances of the solar wind and photon pressure. The orientation of the spacecraft with respect to the Sun changes very slowly. The Sun appears moves along a cone with a 30° half angle aligned with the spacecraft's cylindrical axis once per year, giving constant illumination. The major source of disturbance in the measurement band is the variation in the solar constant caused by the Sun's normal modes of oscillation, amounting to less than 10 ppm in intensity.
The orbital motion of the antenna sweeps its sensitivity lobes across the sky, giving an amplitude modulation dependent on a source's angular coordinates. Similarly, the Doppler effect gives a phase modulation dependent on a source's angular coordinates. The two effects combine to give directional information about every source. Most of the sources observable by LISA are periodic or quasi-periodic and can be observed for at least a year. The angular position accuracy depends on the signal-to-noise ratio. For the strongest sources, the direction to the source can be determined to about 1 arc minute.
[edit] Licensing
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This work is in the public domain in the United States because it is a work of the United States Federal Government under the terms of Title 17, Chapter 1, Section 105 of the US Code. See Copyright. Note: This only applies to works of the Federal Government and not to the work of any individual U.S. state, territory, commonwealth, county, municipality, or any other subdivision. |
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File history
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| Date/Time | Dimensions | User | Comment | |
|---|---|---|---|---|
| current | 14:56, 13 August 2006 | 1,500×1,125 (165 KB) | Keenan Pepper (Talk | contribs) | (NASA illustration of LISA, taken from http://lisa.jpl.nasa.gov/gallery/lisa-waves.html. High resolution TIFF compressed with "cjpeg" from libjpeg-progs. NASA's description: The three LISA spacecraft will be placed in orbits that) |
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File links
- LIGO
- Laser Interferometer Space Antenna
- Einstein@Home
- MiniGrail
- Portal:Physics
- GEO 600
- LCGT
- Virgo interferometer
- Gravitational wave
- Cosmic gravitational wave background
- Gravitational wave detector
- Big Bang Observer
- Template:Gravitational wave observatories
- TAMA 300
- ACIGA
- AIGO
- Portal:Physics/2008 Selected pictures
- List of space telescopes
- Interferometric gravitational wave detector
- Portal:Physics/Selected picture/May 2008
