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1. Design Interface Mapping for Efficient Free-form Tele-manipulation

   https://doi.org/10.1109/IROS47612.2022.9982149  

   Krishnan, Achyuthan Unni; Lin, Tsung-Chi; Li, Zhi (October 2022, 2022 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS))

   Motion tracking interfaces are intuitive for free-form teleoperation tasks. However, efficient manipulation control can be difficult with such interfaces because of issues like the interference of unintended motions and the limited precision of human motion control. The limitation in control efficiency reduces the operator's performance and increases their workload and frustration during robot teleoperation. To improve the efficiency, we proposed separating controlled degrees of freedom (DoFs) and adjusting the motion scaling ratio of a motion tracking interface. The motion tracking of handheld controllers from a Virtual Reality system was used for the interface. We separated the translation and rotational control into: 1) two controllers held in the dominant and non-dominant hands and 2) hand pose tracking and trackpad inputs of a controller. We scaled the control mapping ratio based on 1) the environmental constraints and 2) the teleoperator's control speed. We further conducted a user study to investigate the effectiveness of the proposed methods in increasing efficiency. Our results show that the separation of position and orientation control into two controllers and the environment-based scaling methods perform better than their alternatives. 

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2. A Comparison Between Joint Space and Task Space Mappings for Dynamic Teleoperation of an Anthropomorphic Robotic Arm in Reaction Tests

   https://doi.org/10.1109/ICRA48506.2021.9561368  

   Wang, Sunyu; Murphy, Kevin; Kenney, Dillan; Ramos, Joao (May 2021, 2021 IEEE International Conference on Robotics and Automation (ICRA))

   Teleoperation—i.e., controlling a robot with human motion—proves promising in enabling a humanoid robot to move as dynamically as a human. But how to map human motion to a humanoid robot matters because a human and a humanoid robot rarely have identical topologies and dimensions. This work presents an experimental study that utilizes reaction tests to compare joint space and task space mappings for dynamic teleoperation of an anthropomorphic robotic arm that possesses human-level dynamic motion capabilities. The experimental results suggest that the robot achieved similar and, in some cases, human-level dynamic performances with both mappings for the six participating human subjects. All subjects became proficient at teleoperating the robot with both mappings after practice, despite that the subjects and the robot differed in size and link length ratio and that the teleoperation required the subjects to move unintuitively. Yet, most subjects developed their teleoperation proficiencies more quickly with task space mapping than with joint space mapping after similar amounts of practice. This study also indicates the potential values of three-dimensional task space mapping, a teleoperation training simulator, and force feedback to the human pilot for intuitive and dynamic teleoperation of a humanoid robot’s arms. 

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3. A Comparison Between Joint Space and Task Space Mappings for Dynamic Teleoperation of an Anthropomorphic Robotic Arm in Reaction Tests

   Wang, Sunyu; Murphy, Kevin; Kenney, Dillan; Ramos, Joao (January 2021, IEEE International Conference on Robotics and Automation)

   null (Ed.)

   Teleoperation—i.e., controlling a robot with human motion—proves promising in enabling a humanoid robot to move as dynamically as a human. But how to map human motion to a humanoid robot matters because a human and a humanoid robot rarely have identical topologies and dimensions. This work presents an experimental study that utilizes reaction tests to compare joint space and task space mappings for dynamic teleoperation of an anthropomorphic robotic arm that possesses human-level dynamic motion capabilities. The experimental results suggest that the robot achieved similar and, in some cases, human-level dynamic performances with both mappings for the six participating human subjects. All subjects became proficient at teleoperating the robot with both mappings after practice, despite that the subjects and the robot differed in size and link length ratio and that the teleoperation required the subjects to move unintuitively. Yet, most subjects developed their teleoperation proficiencies more quickly with task space mapping than with joint space mapping after similar amounts of practice. This study also indicates the potential values of three-dimensional task space mapping, a teleoperation training simulator, and force feedback to the human pilot for intuitive and dynamic teleoperation of a humanoid robot’s arms. 

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4. Development of Smartphone-Based Human-Robot Interfaces for Individuals with Disabilities

   Lei Wu, Redwan Alqasemi (October 2020, Proceedings of the IEEERSJ International Conference on Intelligent Robots and Systems)

   Persons with disabilities often rely on caregivers or family members to assist in their daily living activities. Robotic assistants can provide an alternative solution if intuitive user interfaces are designed for simple operations. Current humanrobot interfaces are still far from being able to operate in an intuitive way when used for complex activities of daily living (ADL). In this era of smartphones that are packed with sensors, such as accelerometers, gyroscopes and a precise touch screen, robot controls can be interfaced with smartphones to capture the user’s intended operation of the robot assistant. In this paper, we review the current popular human-robot interfaces, and we present three novel human-robot smartphone-based interfaces to operate a robotic arm for assisting persons with disabilities in their ADL tasks. Useful smartphone data, including 3 dimensional orientation and 2 dimensional touchscreen positions, are used as control variables to the robot motion in Cartesian teleoperation. In this paper, we present the three control interfaces, their implementation on a smartphone to control a robotic arm, and a comparison between the results on using the three interfaces for three different ADL tasks. The developed interfaces provide intuitiveness, low cost, and environmental adaptability. 

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5. Exploring Human-Machine Interfaces for Teleoperation of Excavator

   https://doi.org/10.1061/9780784483961.079  

   Lee, Jin Sol; Ham, Youngjib (March 2022, ASCE Construction Research Congress 2022)

   With the advancement of automation and robotic technologies, the teleoperation has been leveraged as a promising solution for human workers in a hazardous construction work environment. Since human operators and construction sites are separated in a distance, teleoperation requires a seamless human-machine interface, an intermediate medium, to communicate between humans and machines in construction sites. Several types of teleoperation interfaces including conventional joysticks, haptic devices, graphic user interfaces, auditory interfaces, and tactile interfaces have been developed to control and command construction robotics remotely. The ultimate goal of human-machine interfaces for remote operations is to make intuitive sensory channels that can provide and receive enough information while reducing the associated cognitive and physical load on human operators. Previously developed interfaces have tried to achieve such goals, but each interface still has challenges that should be assessed for enhancing the future teleoperation application in construction workplaces. This paper examines different human-machine interfaces for excavator teleoperation in terms of its on-site usability and intuitiveness. The capabilities of the interfaces for excavator teleoperation are evaluated based on their limitations and requirements. The outcome is expected to provide better understanding of teleoperation interfaces for excavators and guiding future directions for addressing underlying challenges. 

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