An Integrated Traverse Planner and Analysis Tool for Planetary Exploration
نویسندگان
چکیده
Future planetary explorations will require surface traverses of unprecedented frequency, length, and duration. As a result, there is need for exploration support tools to maximize productivity, scientific return, and safety. The Massachusetts Institute of Technology is currently developing such a system, called the Surface Exploration Traverse Analysis and Navigation Tool (SEXTANT). The goal of this system is twofold: to allow for realistic simulations of traverses in order to assist with hardware design, and to give astronauts an aid that will allow for more autonomy in traverse planning and re-planning. SEXTANT is a MATLAB-based tool that incorporates a lunar elevation model created from data from the Lunar Orbiter Laser Altimeter instrument aboard the Lunar Reconnaissance Orbiter spacecraft. To assist in traverse planning, SEXTANT determines the most efficient path across a planetary surface for astronauts or transportation rovers between user-specified Activity Points. The path efficiency is derived from any number of metrics: the traverse distance, traverse time, or the explorer’s energy consumption. The generated path, display of traverse obstacles, and selection of Activity Points are visualized in a 3D mapping interface. After a traverse has been planned, SEXTANT is capable of computing the most efficient path back home, or “walkback”, from any point along the traverse – an important capability for emergency operations. SEXTANT also has the ability to determine shadowed and sunlit areas along a lunar traverse. This data is used to compute the thermal load on suited astronauts and the solar power generation capacity of rovers over the entire traverse. These both relate directly to the explorer’s consumables, which place strict constraints on the traverse. This paper concludes by presenting three example traverses, detailing how SEXTANT can be used to plan and modify paths for both explorer types.
منابع مشابه
CAMPOUT: a control architecture for tightly coupled coordination of multirobot systems for planetary surface exploration
Exploration of high risk terrain areas such as cliff faces and site construction operations by autonomous robotic systems on Mars requires a control architecture that is able to autonomously adapt to uncertainties in knowledge of the environment. We report on the development of a software/hardware framework for cooperating multiple robots performing such tightly coordinated tasks. This work bui...
متن کاملMission Planning for the Sun-Synchronous Navigation Field Experiment
This paper describes the development and testing of software to enable an experimental, solar-powered rover to reason about solar energy, rover power expenditure, terrain and time in creating extended route plans in a planetary analog environment. Unlike previous path planners, this new software solves the coupled path, path timing and resource management problem that will be critical for futur...
متن کاملAn Autonomous Sensor-Based Path-Planner for Planetary Microrovers
With the success of Mars Pathfinder’s Sojourner rover, a new era of planetary exploration has opened, with demand for highly capable mobile robots. These robots must be able to traverse long distances over rough, unknown terrain autonomously, under severe resource constraints. Based on the authors’ firsthand experience with the Mars Pathfinder mission, this paper reviews issues which are critic...
متن کاملDevelopment of a Planetary Entry Systems Synthesis Tool for Conceptual Design and Analysis
A Planetary Entry Systems Synthesis Tool, with applications to conceptual design and modeling of entry systems has been developed. This tool is applicable to exploration missions that employ entry, descent and landing or aerocapture. An integrated framework brings together relevant disciplinary analyses and enables rapid design and analysis of the atmospheric entry mission segment. Tool perform...
متن کاملIntegrating Simulated Tensegrity Models with Efficient Motion Planning for Planetary Navigation
Tensegrity-based robots use compression elements and tension cables to create lightweight structures that can reconfigure their shape. These characteristics are especially suited for planetary exploration, including for hard to traverse areas, such as lava tubes. While these capabilities are desirable for transporting these robots beyond Earth as well as reducing material costs, they complicate...
متن کامل