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Spacecraft dynamics and control is one of the areas in which our lab has been active for a number of years. The problems that we have been particularly interested in pertain to spacecraft GN&C, autonomous constraint avoidance, and distributed spacecraft control. Some of these problems are motivated projects that PI Mehran Mesbahi was involved at the Jet Propulsion Laboratory, that included attitude control design and analysis, attitude estimation, and Saturn orbit insertion for the Cassini spacecraft, distributed control systems for missions such as Deep Space 3, Starlight, and Terrestrial Planet Finder, and attitude and articulation subsystem for Shuttle Radar Topography Mission. Over the years, our group has contributed to various facets of guidance, navigation, control, optimization, and estimation problems related to space systems. Our recent work involve adoption of quaternion and dual quaternion representations to provide convex optimization-based solutions to a number of outstanding problems in spacecraft autonomy such as constrained pinpoint landing, distributed actuation, and constrained attitude control, for monolithic and distributed space systems.<\/p>\n
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The RAIN Lab is also the lead on the design and testing of the Attitude Determination and Control Subsystem (ADCS) for the University of Washington\u2019s HuskySat-1. This work is in collaboration with the UW Satellite team and industry advisors from Planetary Resources. Our group is developing an experimental control algorithm that will demonstrate the capability of optimization based control for spacecraft reorientation in LEO.\u00a0 The anticipated delivery date is August 2018.<\/p>\n
Project Sponsors: HuskySat-1, NASA Johnson Space Center, NASA Jet Propulsion Laboratory<\/p>\n
Recent Publications:<\/p>\n
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Flight dynamics and control is one of the cornerstones of aerospace engineering. This discipline aims is to understand the dynamics of the aircraft, quantify various notions of stability and performance for distinct flight conditions, and then design control and estimation algorithms that lead to satisfying various notions of performance and stability criteria. In our group, we examine flight dynamics and control particularly as it relates to optimized and high performance flight systems for various aerial vehicles, including commercial airplanes and unmanned aerial vehicles that can support such missions as search and rescue, fire fighting, and energy optimized long endurance missions. Our approach aims to provide a systematic means of designing highly efficient and constrained systems that are not amenable to design by traditional methods. In this venue, we provide efficient algorithmic tools for criteria such as energy optimization, collision avoidance, trajectory planning, gust load alleviation, energy optimization for hybrid and electric aircraft, total energy management, solar-powered UAVs, among others.<\/p>\n
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Project Sponsors: Boeing, FAA, AFOSR<\/p>\n
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As networks become ubiquitous in many areas of engineering, it has become of paramount importance to examine how the network and its structure effect the dynamic properties of the overall system, such as its stability, performance, and robustness, both in the random and deterministic settings. We also consider some of the more fundamental system-theoretic questions such as controllability and observability of networked systems. Our research team examines a wide range questions from theoretical point of view as well as their ramifications for systems such as multiple spacecraft formation flying, distributed robotics, UAV formations, heterogeneous dynamic networks, and more recently, in the setting of social and biological networks.<\/p>\n
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