Space Interferometry Mission starlight and metrology subsystems

Ames, Lawrence L.; Barrett, Stephanie; Calhoon, Stuart J.; Kvamme, E. Todd; Mason, James; Oseas, Jeffrey M.; Pryor, Mark; Schaechter, D. B.; Stubbs, David

doi:10.1117/12.460693

Cited by 6 publications

(1 citation statement)

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“…The SIM internal metrology launcher is located inside of the Astrometric Beam Combiner (ABC), where a truncated mirror behind the main beam combiner optics is used to inject the internal metrology measurement beams into the starlight optics train [13]. The truncated mirror reflects the annular starlight to the starlight camera.…”

Section: Design Considerations For Simmentioning

confidence: 99%

SIM internal metrology beam launcher development

et al. 2003

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To accomplish micro-arcsecond astrometric measurement, stellar interferometers such as SIM require the measurement of internal optical path length delay with an accuracy of~10 picometers level. A novel common-path laser heterodyne interferometer suitable for this application was proposed and demonstrated at JPL. In this paper, we present some of the experimental results from a laboratory demonstration unit and design considerations for SIM's internal metrology beam launcher.

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Section: Design Considerations For Simmentioning

confidence: 99%

SIM internal metrology beam launcher development

et al. 2003

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A Scheme for On‐Orbit Calibration of theSpace Interferometry MissionBased on Spacecraft Maneuvering

Papalexandris¹,

Milman

Shaklan³

2003

PUBL ASTRON SOC PAC

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ABSTRACT. The Space Interferometry Mission (SIM), part of NASA's Origins Program, aims at the detection of planetary systems around distant stars. The astrometric observations of the SIM instrument are performed via high-accuracy path-length measurements with a system of three Michelson-type white-light stellar interferometers. A procedure for on-orbit calibration of the instrument error function is described, along with a proof of the concept's viability. On a given grid of stars, the procedure generates approximations of the gradient of the instrument error function at a discrete set of field points corresponding to the star locations via a specialized set of maneuvers of the spacecraft. These gradient approximations are then used to estimate the error function via a least-squares procedure in a manner that is analogous to the wave-front reconstruction problem in adaptiveoptics systems. An error analysis of the procedure is presented that provides further insights into the connections between instrument errors and the grid reduction solution. Finally, numerical results are presented on a randomly generated grid of stars that demonstrate the feasibility of the method.

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