Teleoperation and Visualization Interfaces for Remote Intervention in Space
Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore...
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| Vydáno v: | Frontiers in robotics and AI Ročník 8; s. 747917 |
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| Hlavní autoři: | , , , , , |
| Médium: | Journal Article |
| Jazyk: | angličtina |
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Goddard Space Flight Center
Frontiers Media
01.12.2021
Frontiers Media S.A |
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| ISSN: | 2296-9144, 2296-9144 |
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| Abstract | Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore the control and visualization interfaces available to those operators, taking into account the challenges due to significant telemetry time delay. We consider one motivating application of remote teleoperation, which is ground-based control of a robot on-orbit for satellite servicing. This paper presents a model-based architecture that: 1) improves visualization and situation awareness, 2) enables more effective human/robot interaction and control, and 3) detects task failures based on anomalous sensor feedback. We illustrate elements of the architecture by drawing on 10 years of our research in this area. The paper further reports the results of several multi-user experiments to evaluate the model-based architecture, on ground-based test platforms, for satellite servicing tasks subject to round-trip communication latencies of several seconds. The most significant performance gains were obtained by enhancing the operators’ situation awareness via improved visualization and by enabling them to precisely specify intended motion. In contrast, changes to the control interface, including model-mediated control or an immersive 3D environment, often reduced the reported task load but did not significantly improve task performance. Considering the challenges of fully autonomous intervention, we expect that some form of teleoperation will continue to be necessary for robotic in-situ servicing, assembly, and manufacturing tasks for the foreseeable future. We propose that effective teleoperation can be enabled by modeling the remote environment, providing operators with a fused view of the real environment and virtual model, and incorporating interfaces and control strategies that enable interactive planning, precise operation, and prompt detection of errors. |
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| AbstractList | Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore the control and visualization interfaces available to those operators, taking into account the challenges due to significant telemetry time delay. We consider one motivating application of remote teleoperation, which is ground-based control of a robot on-orbit for satellite servicing. This paper presents a model-based architecture that: 1) improves visualization and situation awareness, 2) enables more effective human/robot interaction and control, and 3) detects task failures based on anomalous sensor feedback. We illustrate elements of the architecture by drawing on 10 years of our research in this area. The paper further reports the results of several multi-user experiments to evaluate the model-based architecture, on ground-based test platforms, for satellite servicing tasks subject to round-trip communication latencies of several seconds. The most significant performance gains were obtained by enhancing the operators' situation awareness
improved visualization and by enabling them to precisely specify intended motion. In contrast, changes to the control interface, including model-mediated control or an immersive 3D environment, often reduced the reported task load but did not significantly improve task performance. Considering the challenges of fully autonomous intervention, we expect that some form of teleoperation will continue to be necessary for robotic
servicing, assembly, and manufacturing tasks for the foreseeable future. We propose that effective teleoperation can be enabled by modeling the remote environment, providing operators with a fused view of the real environment and virtual model, and incorporating interfaces and control strategies that enable interactive planning, precise operation, and prompt detection of errors. Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore the control and visualization interfaces available to those operators, taking into account the challenges due to significant telemetry time delay. We consider one motivating application of remote teleoperation, which is ground-based control of a robot on-orbit for satellite servicing. This paper presents a model-based architecture that: 1) improves visualization and situation awareness, 2) enables more effective human/robot interaction and control, and 3) detects task failures based on anomalous sensor feedback. We illustrate elements of the architecture by drawing on 10 years of our research in this area. The paper further reports the results of several multi-user experiments to evaluate the model-based architecture, on ground-based test platforms, for satellite servicing tasks subject to round-trip communication latencies of several seconds. The most significant performance gains were obtained by enhancing the operators’ situation awareness via improved visualization and by enabling them to precisely specify intended motion. In contrast, changes to the control interface, including model-mediated control or an immersive 3D environment, often reduced the reported task load but did not significantly improve task performance. Considering the challenges of fully autonomous intervention, we expect that some form of teleoperation will continue to be necessary for robotic in-situ servicing, assembly, and manufacturing tasks for the foreseeable future. We propose that effective teleoperation can be enabled by modeling the remote environment, providing operators with a fused view of the real environment and virtual model, and incorporating interfaces and control strategies that enable interactive planning, precise operation, and prompt detection of errors. Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore the control and visualization interfaces available to those operators, taking into account the challenges due to significant telemetry time delay. We consider one motivating application of remote teleoperation, which is ground-based control of a robot on-orbit for satellite servicing. This paper presents a model-based architecture that: 1) improves visualization and situation awareness, 2) enables more effective human/robot interaction and control, and 3) detects task failures based on anomalous sensor feedback. We illustrate elements of the architecture by drawing on 10 years of our research in this area. The paper further reports the results of several multi-user experiments to evaluate the model-based architecture, on ground-based test platforms, for satellite servicing tasks subject to round-trip communication latencies of several seconds. The most significant performance gains were obtained by enhancing the operators’ situation awareness via improved visualization and by enabling them to precisely specify intended motion. In contrast, changes to the control interface, including model-mediated control or an immersive 3D environment, often reduced the reported task load but did not significantly improve task performance. Considering the challenges of fully autonomous intervention, we expect that some form of teleoperation will continue to be necessary for robotic in-situ servicing, assembly, and manufacturing tasks for the foreseeable future. We propose that effective teleoperation can be enabled by modeling the remote environment, providing operators with a fused view of the real environment and virtual model, and incorporating interfaces and control strategies that enable interactive planning, precise operation, and prompt detection of errors. Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore the control and visualization interfaces available to those operators, taking into account the challenges due to significant telemetry time delay. We consider one motivating application of remote teleoperation, which is ground-based control of a robot on-orbit for satellite servicing. This paper presents a model-based architecture that: 1) improves visualization and situation awareness, 2) enables more effective human/robot interaction and control, and 3) detects task failures based on anomalous sensor feedback. We illustrate elements of the architecture by drawing on 10 years of our research in this area. The paper further reports the results of several multi-user experiments to evaluate the model-based architecture, on ground-based test platforms, for satellite servicing tasks subject to round-trip communication latencies of several seconds. The most significant performance gains were obtained by enhancing the operators’ situation awareness via improved visualization and by enabling them to precisely specify intended motion. In contrast, changes to the control interface, including model-mediated control or an immersive 3D environment, often reduced the reported task load but did not significantly improve task performance. Considering the challenges of fully autonomous intervention, we expect that some form of teleoperation will continue to be necessary for robotic in-situ servicing, assembly, and manufacturing tasks for the foreseeable future. We propose that effective teleoperation can be enabled by modeling the remote environment, providing operators with a fused view of the real environment and virtual model, and incorporating interfaces and control strategies that enable interactive planning, precise operation, and prompt detection of errors. Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore the control and visualization interfaces available to those operators, taking into account the challenges due to significant telemetry time delay. We consider one motivating application of remote teleoperation, which is ground-based control of a robot on-orbit for satellite servicing. This paper presents a model-based architecture that: 1) improves visualization and situation awareness, 2) enables more effective human/robot interaction and control, and 3) detects task failures based on anomalous sensor feedback. We illustrate elements of the architecture by drawing on 10 years of our research in this area. The paper further reports the results of several multi-user experiments to evaluate the model-based architecture, on ground-based test platforms, for satellite servicing tasks subject to round-trip communication latencies of several seconds. The most significant performance gains were obtained by enhancing the operators' situation awareness via improved visualization and by enabling them to precisely specify intended motion. In contrast, changes to the control interface, including model-mediated control or an immersive 3D environment, often reduced the reported task load but did not significantly improve task performance. Considering the challenges of fully autonomous intervention, we expect that some form of teleoperation will continue to be necessary for robotic in-situ servicing, assembly, and manufacturing tasks for the foreseeable future. We propose that effective teleoperation can be enabled by modeling the remote environment, providing operators with a fused view of the real environment and virtual model, and incorporating interfaces and control strategies that enable interactive planning, precise operation, and prompt detection of errors.Approaches to robotic manufacturing, assembly, and servicing of in-space assets range from autonomous operation to direct teleoperation, with many forms of semi-autonomous teleoperation in between. Because most approaches require one or more human operators at some level, it is important to explore the control and visualization interfaces available to those operators, taking into account the challenges due to significant telemetry time delay. We consider one motivating application of remote teleoperation, which is ground-based control of a robot on-orbit for satellite servicing. This paper presents a model-based architecture that: 1) improves visualization and situation awareness, 2) enables more effective human/robot interaction and control, and 3) detects task failures based on anomalous sensor feedback. We illustrate elements of the architecture by drawing on 10 years of our research in this area. The paper further reports the results of several multi-user experiments to evaluate the model-based architecture, on ground-based test platforms, for satellite servicing tasks subject to round-trip communication latencies of several seconds. The most significant performance gains were obtained by enhancing the operators' situation awareness via improved visualization and by enabling them to precisely specify intended motion. In contrast, changes to the control interface, including model-mediated control or an immersive 3D environment, often reduced the reported task load but did not significantly improve task performance. Considering the challenges of fully autonomous intervention, we expect that some form of teleoperation will continue to be necessary for robotic in-situ servicing, assembly, and manufacturing tasks for the foreseeable future. We propose that effective teleoperation can be enabled by modeling the remote environment, providing operators with a fused view of the real environment and virtual model, and incorporating interfaces and control strategies that enable interactive planning, precise operation, and prompt detection of errors. |
| Audience | PUBLIC |
| Author | Deguet, Anton Vagvolgyi, Balazs P. Pryor, Will Kazanzides, Peter Leonard, Simon Whitcomb, Louis L. |
| AuthorAffiliation | 1 Department of Computer Science, Johns Hopkins University, Baltimore , MD , United States 2 Laboratory for Computational Sensing and Robotics, Johns Hopkins University, Baltimore , MD , United States 3 Department of Mechanical Engineering, Johns Hopkins University, Baltimore , MD , United States |
| AuthorAffiliation_xml | – name: 1 Department of Computer Science, Johns Hopkins University, Baltimore , MD , United States – name: 2 Laboratory for Computational Sensing and Robotics, Johns Hopkins University, Baltimore , MD , United States – name: 3 Department of Mechanical Engineering, Johns Hopkins University, Baltimore , MD , United States |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/34926590$$D View this record in MEDLINE/PubMed |
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| Cites_doi | 10.1007/s11235-015-0034-5 10.1109/70.258056 10.1177/0278364904045563 10.1177/0278364907084590 10.1109/mra.2011.2181749 10.1117/12.46299 10.1162/pres.1992.1.1.29 10.1109/48.659450 10.1037/e477812004-001 10.1109/70.258052 10.1109/70.238286 10.1023/a:1011256128651 10.1115/1.3139652 10.1109/lra.2018.2864358 10.1080/00423110412331290446 |
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| Copyright | Copyright Determination: PUBLIC_USE_PERMITTED Copyright © 2021 Kazanzides, Vagvolgyi, Pryor, Deguet, Leonard and Whitcomb. Copyright © 2021 Kazanzides, Vagvolgyi, Pryor, Deguet, Leonard and Whitcomb. 2021 Kazanzides, Vagvolgyi, Pryor, Deguet, Leonard and Whitcomb |
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| Keywords | Teleoperation Satellite Servicing Space Robotics Scene Modeling Model-Mediated Control teleoperation model-mediated control space robotics satellite servicing scene modeling |
| Language | English |
| License | Copyright © 2021 Kazanzides, Vagvolgyi, Pryor, Deguet, Leonard and Whitcomb. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms. |
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| Notes | GSFC Goddard Space Flight Center ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 Reviewed by: Koki Ho, Georgia Institute of Technology, United States Kevin Cleary, Children’s National Hospital, United States This article was submitted to Space Robotics, a section of the journal Frontiers in Robotics and AI Edited by: Craig R. Carignan, University of Maryland, United States |
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| References | Niemeyer (B24) 2004; 23 Ince (B9) 1991 Gadre (B5) 2019 Spain (B33) 1991 Milgram (B22) 1994; 77 Kandaswamy (B11) 2014 Hashtrudi-Zaad (B7) 2000 Sayers (B30) 1998; 23 Vahidi (B38) 2005; 43 Sheridan (B31) 1993; 9 Spong (B34) 2006 Bejczy (B1) 1990 Mitra (B23) 2008; 27 Merlet (B21) 1987 Pryor (B26) 2019 Tsai (B35) 1988 Hirzinger (B8) 1993; 9 Chitta (B3) 2012; 19 Kazanzides (B15) 2014 Li (B18) 2015 Hart (B6) 2006 Lane (B16) 2001; 11 Pryor (B25) 2020 Xia (B41) 2012 Rosenberg (B29) 1993 Sheridan (B32) 1992 Leonard (B17) 2015 Kapoor (B12) 2006 Vozar (B40) Vagvolgyi (B36) 2017 Kam (B10) 2015; 60 Kazanzides (B14) 1989 Vozar (B39) Chen (B2) 2017 Mahmood (B20) 2020 Quintero (B27) 2018 Raibert (B28) 1981; 103 Li (B19) 2016 Xia (B42) 2013 Yoshikawa (B43) 1993; 9 Karayiannidis (B13) 2006 Funda (B4) 1992; 1 Vagvolgyi (B37) 2018; 3 |
| References_xml | – start-page: 6434 year: 2014 ident: B15 article-title: An open-source research kit for the da Vinci® surgical system – start-page: 2834 year: 2016 ident: B19 article-title: Task Frame Estimation during Model-Based Teleoperation for Satellite Servicing – volume-title: Telerobotics, Automation, and Human Supervisory Control year: 1992 ident: B32 – volume: 60 start-page: 337 year: 2015 ident: B10 article-title: Rviz: a Toolkit for Real Domain Data Visualization publication-title: Telecommun Syst. doi: 10.1007/s11235-015-0034-5 – start-page: 4562 year: 2015 ident: B18 article-title: Parameter Estimation and Anomaly Detection while Cutting Insulation during Telerobotic Satellite Servicing – start-page: 3107 year: 2000 ident: B7 article-title: Analysis and Evaluation of Stability and Performance Robustness for Teleoperation Control Architectures – start-page: 407 year: 1990 ident: B1 article-title: Predictive Displays and Shared Compliance Control for Time-Delayed Telemanipulation – start-page: 2707 year: 2019 ident: B5 article-title: End-user Robot Programming Using Mixed Reality – start-page: 4418 year: 2015 ident: B17 article-title: Registration of Planar Virtual Fixtures by Using Augmented Reality with Dynamic Textures – volume: 9 start-page: 649 year: 1993 ident: B8 article-title: Sensor-based Space Robotics-ROTEX and its Telerobotic Features publication-title: IEEE Trans. Robot. Automat. doi: 10.1109/70.258056 – start-page: 904 volume-title: Proceedings of the Human Factors and Ergonomics Society Annual Meeting year: 2006 ident: B6 article-title: NASA-task Load index (NASA-TLX); 20 Years Later – start-page: 5059 year: 2012 ident: B41 article-title: Augmented Reality Environment with Virtual Fixtures for Robotic Telemanipulation in Space – start-page: 231 year: 2006 ident: B12 article-title: Constrained Control for Surgical Assistant Robots – volume: 23 start-page: 873 year: 2004 ident: B24 article-title: Telemanipulation with Time Delays publication-title: Int. J. Robotics Res. doi: 10.1177/0278364904045563 – volume-title: Robot Modeling and Control year: 2006 ident: B34 – start-page: 1838 year: 2018 ident: B27 article-title: Robot Programming through Augmented Trajectories in Augmented Reality – volume: 77 start-page: 1321 year: 1994 ident: B22 article-title: A Taxonomy of Mixed Reality Visual Displays publication-title: IEICE Trans. Inf. Syst. – start-page: 4244 ident: B39 article-title: Preliminary Study of Virtual Nonholonomic Constraints for Time-Delayed Teleoperation – volume: 27 start-page: 253 year: 2008 ident: B23 article-title: Model-mediated Telemanipulation publication-title: Int. J. Robotics Res. doi: 10.1177/0278364907084590 – start-page: 467 year: 2014 ident: B11 article-title: Strategies and Models for Cutting Satellite Insulation in Telerobotic Servicing Missions – volume: 19 start-page: 18 year: 2012 ident: B3 article-title: MoveIt! [ROS Topics] publication-title: IEEE Robot. Automat. Mag. doi: 10.1109/mra.2011.2181749 – start-page: 92 year: 1989 ident: B14 article-title: Dual-drive Force/velocity Control: Implementation and Experimental Results – start-page: 103 volume-title: SPIE, Stereoscopic Displays and Applications III year: 1991 ident: B33 article-title: Stereoscopic versus Orthogonal View Displays for Performance of a Remote Manipulation Task doi: 10.1117/12.46299 – start-page: 4424 ident: B40 article-title: Experimental Evaluation of Force Control for Virtual-Fixture-Assisted Teleoperation for On-Orbit Manipulation of Satellite thermal Blanket Insulation – start-page: 1903 year: 2020 ident: B20 article-title: Visual Monitoring and Servoing of a Cutting Blade during Telerobotic Satellite Servicing – volume: 1 start-page: 29 year: 1992 ident: B4 article-title: Teleprogramming: Toward Delay-Invariant Remote Manipulation publication-title: Presence: Teleoperators & Virtual Environments doi: 10.1162/pres.1992.1.1.29 – start-page: 1055 year: 1987 ident: B21 article-title: C-surface Applied to the Design of an Hybrid Force-Position Robot Controller – volume: 23 start-page: 60 year: 1998 ident: B30 article-title: Teleprogramming for Subsea Teleoperation Using Acoustic Communication publication-title: IEEE J. Oceanic Eng. doi: 10.1109/48.659450 – start-page: 4775 year: 2019 ident: B26 article-title: Experimental Evaluation of Teleoperation Interfaces for Cutting of Satellite Insulation – volume-title: A Scalable, High-Performance, Real-Time Control Architecture with Application to Semi-autonomous Teleoperation year: 2017 ident: B2 – start-page: 554 year: 1988 ident: B35 article-title: Real Time Versatile Robotics Hand/eye Calibration Using 3D Machine Vision – volume-title: The Use of Virtual Fixtures to Enhance Operator Performance in Time Delayed Teleoperation year: 1993 ident: B29 doi: 10.1037/e477812004-001 – volume: 9 start-page: 592 year: 1993 ident: B31 article-title: Space Teleoperation through Time Delay: Review and Prognosis publication-title: IEEE Trans. Robot. Automat. doi: 10.1109/70.258052 – start-page: 1083 volume-title: IEEE Intl. Conf. On Systems, Man, and Cybernetics (SMC) year: 1991 ident: B9 article-title: Virtuality and Reality: a Video/graphics Environment for Teleoperation – start-page: 1857 year: 2020 ident: B25 article-title: Interactive Planning and Supervised Execution for High-Risk, High-Latency Teleoperation – start-page: 3538 year: 2006 ident: B13 article-title: An Adaptive Law for Slope Identification and Force Position Regulation Using Motion Variables – start-page: 1479 year: 2013 ident: B42 article-title: Model-based Telerobotic Control with Virtual Fixtures for Satellite Servicing Tasks – volume: 9 start-page: 220 year: 1993 ident: B43 article-title: Dynamic Hybrid Position/force Control of Robot Manipulators-On-Line Estimation of Unknown Constraint publication-title: IEEE Trans. Robot. Automat. doi: 10.1109/70.238286 – volume: 11 start-page: 49 year: 2001 ident: B16 article-title: Advanced Operator Interface Design for Complex Space Telerobots publication-title: Autonomous Robots doi: 10.1023/a:1011256128651 – volume: 103 start-page: 126 year: 1981 ident: B28 article-title: Hybrid Position/force Control of Manipulators publication-title: ASME J. Dynamic Systems, Measurement, Control. doi: 10.1115/1.3139652 – volume: 3 start-page: 4241 year: 2018 ident: B37 article-title: Scene Modeling and Augmented Virtuality Interface for Telerobotic Satellite Servicing publication-title: IEEE Robot. Autom. Lett. doi: 10.1109/lra.2018.2864358 – start-page: 3826 year: 2017 ident: B36 article-title: Augmented Virtuality for Model-Based Teleoperation – volume: 43 start-page: 31 year: 2005 ident: B38 article-title: Recursive Least Squares with Forgetting for Online Estimation of Vehicle Mass and Road Grade: Theory and Experiments publication-title: Vehicle Syst. Dyn. doi: 10.1080/00423110412331290446 |
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| SubjectTerms | Cybernetics, Artificial Intelligence And Robotics model-mediated control Robotics and AI satellite servicing scene modeling space robotics teleoperation |
| Title | Teleoperation and Visualization Interfaces for Remote Intervention in Space |
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