Resource-Aware Planning for Shadowed and Uncertain Domains

NASA's Technology Roadmap TA04, Robotics, Telerobotics and Autonomous Systems, identifies autonomous navigation as one of three impact areas for technology development. The proposed work enhances development of autonomous navigation by building on the successes of the Mars Science Laboratory and other rovers' use of locally acquired data to refine and potentially modify Earth-generated plans without human intervention or approval. By adjusting relative parameters in the planning model, Earth-based controllers can set the bounds on local authority, response, and operational capabilities while maximizing operational advantages of locally-centered decision making. Phase II results will advance technologies to TRL 5, ready for assimilation into NASA missions. Existing NASA collaborations will drive infusion of the developed technologies into future missions. Technical Advisor William "Red" Whittaker collaborates deeply with NASA's autonomy experts. Astrobotic intends to produce lunar and planetary rovers encompassing these technologies as build-to-order rovers or as technology licenses. Active Astrobotic contracts with NASA are defining rover missions to carry the RESOLVE payload, excavate on the Moon, and provide data from a lunar mission. Relationships curated through these contracts provide additional paths for technology infusion, and results will be promoted through all NASA partnerships and collaborations.

Resource-aware planning provides significant advances over state-of-art autonomous navigation, mapping, and localization for terrestrial applications. The need for low cost, computationally inexpensive, and easy to integrate autonomous navigation and mapping applies broadly to terrestrial applications particularly those that are GPS-denied. Potential applications include driverless cars, search and rescue, mining, military UGVs and UAVs, and agriculture. Vision-guided UAVs offer a particularly good fit for resource-constrained planning. As small UAVs become more common for surveillance and scouting, the need to reduce operator load will become paramount. With a wide array of sensor suites producing dense data sets, enabling vehicles to make decisions on-board within operator-defined bounds allows an operator to concentrate on high-level mission objectives rather than low-level vehicle operations. The proposed work is particularly suited to terrestrial applications where only low-fidelity data is available for initial planning; by creating a provisional plan to be optimized by future high-fidelity measurements, the overall mission objective can be completed with an minimum of waste. The result is an optimized use of limited resources, including overhead time and ground-based manpower. More »