Multidisciplinary Control of a Sparse Interferometric Array Satellite Testbed

Chung, Soon‐Jo; LoBosco, David; Miller, David W.; Blaurock, Carl

doi:10.2514/6.2003-5433

Cited by 4 publications

(6 citation statements)

References 12 publications

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“…Based on the linear model obtained, the pointing and tracking controller was successfully designed and implemented performing a large angle slew maneuver. 21 The controller calculates the error quaternions 22 from the rate gyroscope, the electronic compass/inclinometer and the viewfinder centroiding CCD mixing the mechanical sensors with the optical sensor ͑the viewfinder CCD in Figs. 1 and 13͒.…”

Section: Pointing and Tracking Control Designmentioning

confidence: 99%

ARGOS testbed: study of multidisciplinary challenges of future spaceborne interferometric arrays

2004

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Abstract. Future spaceborne interferometric arrays must meet stringent optical performance and tolerance requirements while exhibiting modularity and acceptable manufacture and integration cost levels. The Massachusetts Institute of Technology (MIT) Adaptive Reconnaissance Golay-3 Optical Satellite (ARGOS) is a wide-angle Fizeau interferometer spacecraft testbed designed to address these research challenges. Designing a space-based stellar interferometer, which requires tight tolerances on pointing and alignment for its apertures, presents unique multidisciplinary challenges in the areas of structural dynamics, controls, and multiaperture phasing active optics. In meeting these challenges, emphasis is placed on modularity in spacecraft subsystems and optics as a means of enabling expandability and upgradeability. A rigorous theory of beam-combining errors for sparse optical arrays is derived and flown down to the design of various subsystems. A detailed elaboration on the optics system and control system is presented based on the performance requirements and beam-combining error tolerances. The space environment is simulated by floating ARGOS on a frictionless airbearing that enables it to track both fast and slow moving targets.

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Section: Pointing and Tracking Control Designmentioning

confidence: 99%

ARGOS testbed: study of multidisciplinary challenges of future spaceborne interferometric arrays

2004

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“…Traditional simulator can also unload the gravity of each link of robot arm. MIT has built several 3-DOF (degree of freedom) air bearing simulators to test the control method of small satellites formation flight [5][6][7]. Those simulators can move on the horizontal plane and rotate around the vertical axis.…”

Section: Introductionmentioning

confidence: 99%

An Air Bearing Facility for Antenna Pointing Mechanism

Yang¹,

Wang²,

Ling³

et al. 2018

Proceedings of the 2018 International Conference on Computer Science, Electronics and Communication Engineering (CSECE 2018)

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An air bearing facility is built to test the antenna pointing mechanism of track and data relay satellite. A hierarchical and simultaneous gravity unloading method is proposed to unload the gravity on the ground. The air bearing facility is a two layers structure. Planar air bearings and air spindle are used to unload the gravity of antenna pointing mechanism. An artificial load is designed to replace the antenna. Two joints of antenna pointing mechanism can rotate separately or together freely without the influence of gravity on the ground. The artificial load not only matches the mass, moment of inertial and basic frequency of the antenna, but also solves the coupling problem of moment of both axes. The air bearing facility is designed and established based on the proposed method and analysis. The effectiveness of this facility is proved with the simulation and the experiments and test results.

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“…In fact, many recently built spacecraft simulators either employ automatic mass balancing systems already [2][3][4][5] or plan to upgrade in the future [14]. The automatic mass balancing system is composed of three proof masses on three individual linear stages, which can alter their positions relative to the spacecraft body.…”

mentioning

confidence: 99%

“…To overcome the difficulties associated with the manual balancing, automatic mass balancing systems have been considered in many references [2][3][4][5][6][7][8][9][10][11][12][13]. In fact, many recently built spacecraft simulators either employ automatic mass balancing systems already [2][3][4][5] or plan to upgrade in the future [14].…”

mentioning

confidence: 99%

“…Ground-based spacecraft simulators often use air bearings to simulate frictionless and microgravity space environments. Various air-bearing-based spacecraft simulators have been developed in the past ( [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16]), and a historical review is presented in [17]. Planar air-bearing systems use a set of air pads mounted under the test article to achieve frictionless sliding over a smooth surface.…”

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confidence: 99%

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Automatic Mass Balancing of Air-Bearing-Based Three-Axis Rotational Spacecraft Simulator

Kim

Agrawal

2009

Journal of Guidance, Control, and Dynamics

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Air-bearing-based spacecraft simulators are widely used to develop and verify spacecraft control techniques required by modern spacecraft applications. To create a spacelike environment with ground spacecraft simulators, the effects of gravity should be minimized. For a spherical air-bearing system with 3 rotational degrees of freedom, the center of rotation of the spacecraft simulator should be exactly aligned with the center of gravity. This paper presents the automatic mass balancing method, which compensates for the center of gravity offset from the center of rotation by actuating three proof masses on linear motion stages. Adaptive control of the automatic mass balancing system is used while the balancing masses are actuated in real time. The proposed techniques are implemented on the ground-based three-axis spacecraft simulator for the bifocal relay mirror spacecraft.

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Multidisciplinary Control of a Sparse Interferometric Array Satellite Testbed

Cited by 4 publications

References 12 publications

ARGOS testbed: study of multidisciplinary challenges of future spaceborne interferometric arrays

ARGOS testbed: study of multidisciplinary challenges of future spaceborne interferometric arrays

An Air Bearing Facility for Antenna Pointing Mechanism

Automatic Mass Balancing of Air-Bearing-Based Three-Axis Rotational Spacecraft Simulator

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