Lidar Sensor Performance in Closed-Loop Flight Testing of the Morpheus Rocket-Propelled Lander to a Lunar-Like Hazard Field

For the first time, a suite of three lidar sensors have been used in flight to scan a lunar-like hazard field, identify a safe landing site, and, in concert with an experimental Guidance, Navigation, and Control (GN&C) system, guide the Morpheus autonomous, rocket-propelled, free-flying test bed to a safe landing on the hazard field. The lidar sensors and GN&C system are part of the Autonomous Precision Landing and Hazard Detection and Avoidance Technology (ALHAT) project which has been seeking to develop a system capable of enabling safe, precise crewed or robotic landings in challenging terrain on planetary bodies under any ambient lighting conditions. The 3-D imaging flash lidar is a second generation, compact, real-time, air-cooled instrument developed from a number of cutting-edge components from industry and NASA and is used as part of the ALHAT Hazard Detection System (HDS) to scan the hazard field and build a 3-D Digital Elevation Map (DEM) in near-real time for identifying safe sites. The flash lidar is capable of identifying a 30 cm hazard from a slant range of 1 km with its 8 cm range precision at 1 sigma. The flash lidar is also used in Hazard Relative Navigation (HRN) to provide position updates down to a 250m slant range to the ALHAT navigation filter as it guides Morpheus to the safe site. The Doppler Lidar system has been developed within NASA to provide velocity measurements with an accuracy of 0.2 cm/sec and range measurements with an accuracy of 17 cm both from a maximum range of 2,200 m to a minimum range of several meters above the ground. The Doppler Lidar's measurements are fed into the ALHAT navigation filter to provide lander guidance to the safe site. The Laser Altimeter, also developed within NASA, provides range measurements with an accuracy of 5 cm from a maximum operational range of 30 km down to 1 m and, being a separate sensor from the flash lidar, can provide range along a separate vector. The Laser Altimeter measurements are also fed into the ALHAT navigation filter to provide lander guidance to the safe site. The flight tests served as the culmination of the TRL 6 journey for the lidar suite and included launch from a pad situated at the NASA-Kennedy Space Center Shuttle Landing Facility (SLF) runway, a lunar-like descent trajectory from an altitude of 250m, and landing on a lunar-like hazard field of rocks, craters, hazardous slopes, and safe sites 400m down-range just off the North end of the runway. The tests both confirmed the expected performance and also revealed several challenges present in the flight-like environment which will feed into future TRL advancement of the sensors. The flash lidar identified hazards as small as 30 cm from the maximum slant range of 450 m which Morpheus could provide, however, it was occasionally susceptible to an increase in range noise due to heated air from the Morpheus rocket plume which entered its Field-of-View (FOV). The flash lidar was also susceptible to pre-triggering on dust during the HRN phase which was created during launch and transported by the wind. The Doppler Lidar provided velocity and range measurements to the expected accuracy levels yet it was also susceptible to signal degradation due to air heated by the rocket engine. The Laser Altimeter, operating with a degraded transmitter laser, also showed signal attenuation over a few seconds at a specific phase of the flight due to the heat plume generated by the rocket engine.

[1]  Lars Sjöqvist,et al.  Laser beam propagation in jet engine plume environments: a review , 2008, Security + Defence.

[2]  Farzin Amzajerdian,et al.  Helicopter Flight Test of a Compact, Real-Time 3-D Flash Lidar for Imaging Hazardous Terrain During Planetary Landing , 2013 .

[3]  Farzin Amzajerdian,et al.  Helicopter flight test of 3D imaging flash LIDAR technology for safe, autonomous, and precise planetary landing , 2013, Defense, Security, and Sensing.

[4]  Andrew E. Johnson,et al.  Helicopter Flight Testing of a Real-Time Hazard Detection System for Safe Lunar Landing , 2013 .

[5]  Glenn D. Hines,et al.  Lidar Sensors for Autonomous Landing and Hazard Avoidance , 2013 .

[6]  Farzin Amzajerdian,et al.  Three-dimensional super-resolution: theory, modeling, and field test results. , 2014, Applied optics.

[7]  T. Brady,et al.  The challenge of safe lunar landing , 2010, 2010 IEEE Aerospace Conference.

[8]  C.D. Epp,et al.  Autonomous Landing and Hazard Avoidance Technology (ALHAT) , 2008, 2008 IEEE Aerospace Conference.

[9]  Andrew E. Johnson,et al.  Flight Testing a Real-Time Hazard Detection System for Safe Lunar Landing on the Rocket-Powered Morpheus Vehicle , 2015 .

[10]  Farzin Amzajerdian,et al.  Navigation Doppler lidar sensor for precision altitude and vector velocity measurements: flight test results , 2011, Defense + Commercial Sensing.

[11]  Roger Stettner,et al.  Compact 3D flash lidar video cameras and applications , 2010, Defense + Commercial Sensing.

[12]  Farzin Amzajerdian,et al.  Field Demonstration of a Precision Navigation Lidar System for Space Vehicles , 2013 .

[13]  Farzin Amzajerdian,et al.  A long-distance laser altimeter for terrain relative navigation and spacecraft landing , 2014, Defense + Security Symposium.

[14]  Farzin Amzajerdian,et al.  Utilization of 3D imaging flash lidar technology for autonomous safe landing on planetary bodies , 2010, OPTO.

[15]  Andrew E. Johnson,et al.  Performance evaluation of hazard detection and avoidance algorithms for safe Lunar landings , 2010, 2010 IEEE Aerospace Conference.

[16]  Farzin Amzajerdian,et al.  Flight test performance of a high precision navigation Doppler lidar , 2009, Defense + Commercial Sensing.

[17]  J. B. Davidson,et al.  Development of a Coherent Lidar for Aiding Precision Soft Landing on Planetary Bodies , 2005 .