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Propulsive Reaction Control System Model (2011)

Phan, Linh H. ; Serricchio, Frederick ; Brugarolas, Paul ; [et al.]

In: CASI

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Publication Date: 2019-07-12

Description: This software models a propulsive reaction control system (RCS) for guidance, navigation, and control simulation purposes. The model includes the drive electronics, the electromechanical valve dynamics, the combustion dynamics, and thrust. This innovation follows the Mars Science Laboratory entry reaction control system design, and has been created to meet the Mars Science Laboratory (MSL) entry, descent, and landing simulation needs. It has been built to be plug-and-play on multiple MSL testbeds [analysis, Monte Carlo, flight software development, hardware-in-the-loop, and ATLO (assembly, test and launch operations) testbeds]. This RCS model is a C language program. It contains two main functions: the RCS electronics model function that models the RCS FPGA (field-programmable-gate-array) processing and commanding of the RCS valve, and the RCS dynamic model function that models the valve and combustion dynamics. In addition, this software provides support functions to initialize the model states, set parameters, access model telemetry, and access calculated thruster forces.

Keywords: Man/System Technology and Life Support

Type: NPO-46978 , NASA Tech Briefs, November 2011; 13

Format: application/pdf

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Autonomous Sample Acquisition for Planetary and Small Body Explorations (2000)

Serricchio, Frederick ; Hadaegh, Fred Y. ; Ghavimi, Ali R. ; [et al.]

In: CASI

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Publication Date: 2019-08-15

Description: Robotic drilling and autonomous sample acquisition are considered as the key technology requirements in future planetary or small body exploration missions. Core sampling or subsurface drilling operation is envisioned to be off rovers or landers. These supporting platforms are inherently flexible, light, and can withstand only limited amount of reaction forces and torques. This, together with unknown properties of sampled materials, makes the sampling operation a tedious task and quite challenging. This paper highlights the recent advancements in the sample acquisition control system design and development for the in situ scientific exploration of planetary and small interplanetary missions.

Keywords: Lunar and Planetary Science and Exploration

Format: application/pdf

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Autonomous Landing and Smart Anchoring for In-Situ Exploration of Small Bodies (2000)

Hadaegh, Fred Y. ; Serricchio, Frederick ; Dolgin, Ben ; [et al.]

In: CASI

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Publication Date: 2019-08-15

Description: Future NASA missions include in-situ scientific explorations of small interplanetary objects like comets and asteroids. Sample acquisition systems are envisioned to operate directly from the landers that are anchored to the surface. Landing and anchoring proves to be challenging in the absence of an attitude control system and in the presence of nearly zero-gravity environments with uncertain surface terrain and unknown mechanical properties. This paper presents recent advancements in developing a novel landing and anchoring control system for the exploration of small bodies.

Keywords: Spacecraft Design, Testing and Performance

Format: application/pdf

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Powered Flight Design and Reconstructed Performance Summary for the Mars Science Laboratory Mission (2013)

San Martin, Miguel ; Singh, Gurkirpal ; Davis, Jody ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: The Powered Flight segment of Mars Science Laboratory's (MSL) Entry, Descent, and Landing (EDL) system extends from backshell separation through landing. This segment is responsible for removing the final 0.1% of the kinetic energy dissipated during EDL and culminating with the successful touchdown of the rover on the surface of Mars. Many challenges exist in the Powered Flight segment: extraction of Powered Descent Vehicle from the backshell, performing a 300m divert maneuver to avoid the backshell and parachute, slowing the descent from 85 m/s to 0.75 m/s and successfully lowering the rover on a 7.5m bridle beneath the rocket-powered Descent Stage and gently placing it on the surface using the Sky Crane Maneuver. Finally, the nearly-spent Descent Stage must execute a Flyaway maneuver to ensure surface impact a safe distance from the Rover. This paper provides an overview of the powered flight design, key features, and event timeline. It also summarizes Curiosity's as flown performance on the night of August 5th as reconstructed by the flight team.

Keywords: Spacecraft Design, Testing and Performance; Lunar and Planetary Science and Exploration

Type: AAS 13-424 , AAS/AIAA Spaceflight Mechanics Meeting; Feb 10, 2013 - Feb 14, 2013; Kauai, HI; United States

Format: text

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