Intelligent Robotic Systems for Space Exploration

Read more

Over the last twenty years, automation and robotics have played an increasingly important role in a variety of application domains including manufacturing, hazardous environments, defense, and service industries. Space is a unique environment where power, communications, atmospheric, gravitational, and sensing conditions impose harsh constraints on the ability of both man and machines to function productively.
In this environment, intelligent automation and robotics are essential complements to the capabilities of humans. In the development of the United States Space Program, robotic manipulation systems have increased in importance as the complexity of space missions has grown. Future missions will require the construction, maintenance, and repair of large structures, such as the space station. This volume presents the effords of several groups that are working on robotic solutions to this problem.
Much of the work in this book is related to assembly in space, and especially in-orbit assembly of large truss structures. Many of these so-called truss structures will be assembled in orbit. It is expected that robot manipulators will be used exclusively, or at least provide partial assistance to humans.
Intelligent Robotic Systems for Space Exploration provides detailed algorithms and analysis for assembly of truss structure in space. It reports on actual implementations to date done at NASA's Langley Research Center. The Johnson Space Center, and the Jet Propulsion Laboratory. Other implementations and research done at Rensselaer are also reported. Analysis of robot control problems that are unique to a zero-gravity environment are presented.

List of contents

1 Testbed for Cooperative Robotic Manipulators.- 1.1 Introduction.- 1.2 Purposes of the CIRSSE Testbed.- 1.3 Space-Based Assembly.- 1.4 Issues and Results for Space-Based Robotic Applications.- 1.5 Physical Description of the CIRSSE Testbed.- 1.6 Design of the MCS for the CIRSSE Testbed.- 1.7 High-Level Control of the CIRSSE Testbed.- 1.8 Summary.- 1.9 References.- 2 Automated Assembly.- 2.1 Introduction.- 2.2 Facility and Hardware Description.- 2.3 Assembly Operations.- 2.4 Software Structure.- 2.5 Tests.- 2.6 Current Test Observations and Results.- 2.7 Future Research Opportunities.- 2.8 Conclusions.- 2.9 Appendix A.- 2.10 APPENDIX B.- 2.11 References.- 3 A Truss Joint for Robotic Assembly.- 3.1 Space-Based Assembly.- 3.2 The Robot-Friendly Structural Joint Study.- 3.3 Test Descriptions.- 3.4 Test Results and Evaluation.- 3.5 Conclusions.- 3.6 References.- 4 Hierarchical Planning for Space-Truss Assembly.- 4.1 Introduction.- 4.2 Part I: Assembly Sequence Planning.- 4.3 Part II: Assembly Path Planning.- 4.4 References.- 5 Three-Dimensional Vision.- 5.1 Passive Techniques.- 5.2 Active Techniques.- 5.3 Calibration of Fixed Cameras.- 5.4 Calibration of a Laser Scanner.- 5.5 Three-Dimensional Point Estimation Methods.- 5.6 Description of the CIRSSE 3-D Vision System.- 5.7 References.- 6 CIRSSE Gripper and Controller System.- 6.1 Introduction.- 6.2 Gripper Design Specifications.- 6.3 Mechanical Design.- 6.4 Controller Electronic Design.- 6.5 Controller Software Design.- 6.6 Summary.- 6.7 References.- 7 Simulation of Space Manipulators.- 7.1 Introduction.- 7.2 Notation.- 7.3 Single Manipulator Dynamics.- 7.4 Simulation of Cooperating Manipulators.- 7.5 Conclusion.- 7.6 References.- 8 JPL Telerobot Testbed.- 8.1 Background of the NASA/JPL Telerobot Testbed.- 8.2 System Description.- 8.3 Force and Motion Control Capability.- 8.4 World Model System.- 8.5 Collision Detector.- 8.6 Path Planner.- 8.7 Task Primitives.- 8.8 Conclusions.- 8.9 References.

Summary

Over the last twenty years, automation and robotics have played an increasingly important role in a variety of application domains including manufacturing, hazardous environments, defense, and service industries. Space is a unique environment where power, communications, atmospheric, gravitational, and sensing conditions impose harsh constraints on the ability of both man and machines to function productively.
In this environment, intelligent automation and robotics are essential complements to the capabilities of humans. In the development of the United States Space Program, robotic manipulation systems have increased in importance as the complexity of space missions has grown. Future missions will require the construction, maintenance, and repair of large structures, such as the space station. This volume presents the effords of several groups that are working on robotic solutions to this problem.
Much of the work in this book is related to assembly in space, and especially in-orbit assembly of large truss structures. Many of these so-called truss structures will be assembled in orbit. It is expected that robot manipulators will be used exclusively, or at least provide partial assistance to humans.
Intelligent Robotic Systems for Space Exploration provides detailed algorithms and analysis for assembly of truss structure in space. It reports on actual implementations to date done at NASA's Langley Research Center. The Johnson Space Center, and the Jet Propulsion Laboratory. Other implementations and research done at Rensselaer are also reported. Analysis of robot control problems that are unique to a zero-gravity environment are presented.

Additional text

'The book will be of most use to those in the space industry who are actually concerned with the fabrication of large space structures.' Journal of Aerospace Engineering 1992

Report

'The book will be of most use to those in the space industry who are actually concerned with the fabrication of large space structures.' Journal of Aerospace Engineering 1992