Intelligent, Autonomous, Distributed Vehicle and Electrical Power System Management, Phase I

The proposed innovation, a distributed architecture for intelligent characterization, fault detection/diagnosis/ reconfiguration/replanning/rescheduling, and adaptive execution, substantially leverages large previous NASA investments to assemble the correct set of technologies to implement all aspects of the required intelligent, autonomous vehicle and distributed EPS and other subsystem managers.  Stottler Henke has significant experience in all of the required technologies and has already integrated them, under NASA funding, into a general MAESTRO (Management through intelligent, AdaptivE, autonomouS, faulT identification and diagnosis, Reconfiguration/replanning/rescheduling Optimization) architecture designed to be easily applied to spacecraft subsystem management problems.  We have applied MAESTRO in a current Phase I effort to Electrical Power System (EPS) management and interfaced it with a laboratory instantiation of a cubesat.   Our Research Institution partner, Montana State University (MSU), has designed, built, launched, and operated several satellites with over 14 satellite-years of in-space operations experience.  For this Phase I effort, in addition to providing substantial knowledge, expertise and practical experience, MSU will also provide real satellite telemetry data and supplement the existing laboratory hardware testbed (LabSat), with additional boards for more complex subsystems and the ability to cause real hardware faults, both confined within a single subsystem and faults in one subsystem that cause issues in others.  This new, augmented LabSat will be used for testing our distributed prototype with real hardware failures.  y also plan to field an actual proof of concept prototype onboard one of their future satellites, in-space, at the culmination of a Phase II effort.  This work also leverages and extends NASA’s Glenn Research Center’s Vehicle Autonomous Power Control (APC) Architecture.

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identifier TECHPORT_94641
issued 2019-08-01
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notes <p>The proposed innovation, a distributed architecture for intelligent characterization, fault detection/diagnosis/ reconfiguration/replanning/rescheduling, and adaptive execution, substantially leverages large previous NASA investments to assemble the correct set of technologies to implement all aspects of the required intelligent, autonomous vehicle and distributed EPS and other subsystem managers.&nbsp; Stottler Henke has significant experience in all of the required technologies and has already integrated them, under NASA funding, into a general MAESTRO (Management through intelligent, AdaptivE, autonomouS, faulT identification and diagnosis, Reconfiguration/replanning/rescheduling Optimization) architecture designed to be easily applied to spacecraft subsystem management problems.&nbsp; We have applied MAESTRO in a current Phase I effort to Electrical Power System (EPS) management and interfaced it with a laboratory instantiation of a cubesat.&nbsp;&nbsp; Our Research Institution partner, Montana State University (MSU), has designed, built, launched, and operated several satellites with over 14 satellite-years of in-space operations experience.&nbsp; <strong>For this Phase I effort</strong>, in addition to providing substantial knowledge, expertise and practical experience, MSU will also <strong>provide real satellite telemetry data and supplement the existing laboratory hardware testbed (LabSat), with additional boards for more complex subsystems and the ability to cause real hardware faults, both confined within a single subsystem and faults in one subsystem that cause issues in others.&nbsp; This new, augmented LabSat will be used for testing our distributed prototype with real hardware failures</strong>.&nbsp; y also plan to <strong>field an actual proof of concept prototype onboard one of their future satellites, in-space, at the culmination of a Phase II effort</strong>.&nbsp; This work also leverages and extends NASA&rsquo;s Glenn Research Center&rsquo;s Vehicle Autonomous Power Control (APC) Architecture.</p>
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title Intelligent, Autonomous, Distributed Vehicle and Electrical Power System Management, Phase I