Physics Colloquium - Andrew Johnson (JPL)

Andrew Johnson (JPL)
September 7, 2021
3:45 pm - 4:45 pm
In-person at 1080 Physics Research Building, Smith Seminar room - Virtual Zoom link below - reception at 3:30pm in front of the SSR

Date Range
2021-09-07 15:45:00 2021-09-07 16:45:00 Physics Colloquium - Andrew Johnson (JPL) The Search for Ancient Life on Mars Began with a Safe Landing Dr. Andrew E. Johnson Principal Robotics Systems Engineer Jet Propulsion Laboratory California Institute of Technology In-person in Smith Seminar Room (1080 Smith), masks required Zoom Meeting Zoom Recording Faculty Host: John Beacom Prior mars rover missions have all landed in flat and smooth regions, but for the Mars 2020 mission, which is seeking signs of ancient life, this was no longer acceptable. To maximize the variety of rock samples that will eventually be returned to earth for analysis, the Perseverance rover needed to land in a geologically diverse region with exposed layers. Terrain relief that is ideal for the science obviously poses significant risks for landing, so a new landing capability called Terrain Relative Navigation (TRN) was added to the mission.  TRN takes images of the ground during parachute descent and matches them to a map of the landing area made from orbital imagery.  These matches provide a position fix, like GPS, that tells the lander where it is relative a map of landing hazards that is also generated a-priori from orbital images.  Given its known position relative to the hazards the spacecraft can identify a safe and reachable landing site to target during the final rocket powered phase of landing. This talk will start by describing the scientific goals of the mission and the instruments used to identify ideal samples for return to earth. It will then detail the Terrain Relative Navigation system and the successful targeting results from landing. https://mars.nasa.gov/mars2020/mission/overview/ https://mars.nasa.gov/mars2020/mission/technology/#Terrain-Relative-Navigation Dr. Andrew E. Johnson is a Principal Robotics Systems Engineer in the Guidance and Control Section of the NASA Jet Propulsion Laboratory.  Since joining JPL in 1997, he has been developing technologies and flight systems for autonomous navigation and mapping during descent to planets moons, comets and asteroids. For the Mars Exploration Rovers, he was lead developer for the Descent Image Motion Estimation System, and on Mars 2020 he led the development of the Lander Vision System that provided surface relative position estimates for Terrain Relative Navigation. He was also the manager of the Mars 2020 Guidance Navigation and Control subsystem which included cruise, EDL and surface mission functions.  Andrew received undergraduate degrees in Mathematics and Engineering Physics from the University of Kansas and a Ph.D. in Robotics from Carnegie Mellon University. In-person at 1080 Physics Research Building, Smith Seminar room - Virtual Zoom link below - reception at 3:30pm in front of the SSR America/New_York public

The Search for Ancient Life on Mars Began with a Safe Landing

Dr. Andrew E. Johnson
Principal Robotics Systems Engineer
Jet Propulsion Laboratory
California Institute of Technology

In-person in Smith Seminar Room (1080 Smith), masks required
Zoom Meeting
Zoom Recording

Faculty Host: John Beacom

Prior mars rover missions have all landed in flat and smooth regions, but for the Mars 2020 mission, which is seeking signs of ancient life, this was no longer acceptable. To maximize the variety of rock samples that will eventually be returned to earth for analysis, the Perseverance rover needed to land in a geologically diverse region with exposed layers. Terrain relief that is ideal for the science obviously poses significant risks for landing, so a new landing capability called Terrain Relative Navigation (TRN) was added to the mission.  TRN takes images of the ground during parachute descent and matches them to a map of the landing area made from orbital imagery.  These matches provide a position fix, like GPS, that tells the lander where it is relative a map of landing hazards that is also generated a-priori from orbital images.  Given its known position relative to the hazards the spacecraft can identify a safe and reachable landing site to target during the final rocket powered phase of landing. This talk will start by describing the scientific goals of the mission and the instruments used to identify ideal samples for return to earth. It will then detail the Terrain Relative Navigation system and the successful targeting results from landing.

https://mars.nasa.gov/mars2020/mission/overview/

https://mars.nasa.gov/mars2020/mission/technology/#Terrain-Relative-Navigation

Dr. Andrew E. Johnson is a Principal Robotics Systems Engineer in the Guidance and Control Section of the NASA Jet Propulsion Laboratory.  Since joining JPL in 1997, he has been developing technologies and flight systems for autonomous navigation and mapping during descent to planets moons, comets and asteroids. For the Mars Exploration Rovers, he was lead developer for the Descent Image Motion Estimation System, and on Mars 2020 he led the development of the Lander Vision System that provided surface relative position estimates for Terrain Relative Navigation. He was also the manager of the Mars 2020 Guidance Navigation and Control subsystem which included cruise, EDL and surface mission functions.  Andrew received undergraduate degrees in Mathematics and Engineering Physics from the University of Kansas and a Ph.D. in Robotics from Carnegie Mellon University.

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