Human Teleoperation - A Haptically Enabled Mixed Reality System for Teleultrasound

Black, David R.; Yazdi, Yas Oloumi; Hosseinabadi, Amir Hossein Hadi; Salcudean, Septimiu E.

doi:10.36227/techrxiv.15175869

Cited by 10 publications

(25 citation statements)

References 34 publications

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“…IV. DISCUSSION AND CONCLUSIONS In the original system described in [1], latency tests on the ROS WebSocket implementation showed on average 11.4 ms delay for pose and force transmission over a local network. In contrast, the new system has delays of 1.07 ± 0.57 ms over Ethernet or 5.80 ± 3.30 ms over WiFi on average for the same local network.…”

Section: Human Step Responsementioning

confidence: 97%

“…To the best of our knowledge, no other study has explored the human response when guided by an MR interface. To perform these tests, the prototype developed in [1] was improved to take direct force input from the expert, and a dummy ultrasound probe was designed for the follower, including 6 axis force/torque sensing and 6-DOF position and orientation (pose) tracking (Section II-B). A novel visual control system for the forces was developed, as described in Section II-C. Further rigorous tests of the visual force control and human tracking ability are presented in [31].…”

Section: Ice Candidatesmentioning

confidence: 99%

“…The effectiveness of the approach was demonstrated first using a WebSocket server and Robot Operating System (ROS) on a local wireless network (WLAN), showing large improvement in accuracy and completion time compared to existing teleguidance methods [1]. In the following sections, we describe and characterize a much improved communication system for human teleoperation, testing it in different networks, signal conditions, and data throughputs.…”

Section: B Human Teleoperationmentioning

confidence: 99%

“…Finally, initial results in [1] showed that the system's latency was limited not by the communication latency, but rather by the reaction time of the follower. To quantify this carefully, a series of step response tests were carried out for force and position tracking of the follower.…”

Section: E Human Response Testsmentioning

confidence: 99%

“…Robotic teleoperation and video conference-based teleguidance fall on either end of a spectrum from performance to ease of use and deployment, leaving a large gap for solutions that are both flexible and easy to use and precise and efficient. In a previous paper [1], we introduced a novel concept of "Human Teleoperation" through mixed reality (MR) which bridges this gap. In this control framework, the human follower is controlled as a flexible, cognitive robot such that both the input and the actuation are carried out by people, but with near robot-like latency and precision.…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of Communication and Human Response Latency for (Human) Teleoperation

Black¹,

Andjelic²,

Salcudean³

2022

Preprint

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<p>We previously introduced a novel mixed reality (MR) teleguidance system, human teleoperation [1,2], in which a human (expert) leader and a human (novice) follower are tightly coupled through MR and haptics for applications such as tele-ultrasound. In this paper, a communication system suitable for human teleoperation is presented and characterized in various network conditions, over Ethernet, Wi-Fi, 4G LTE, and 5G. To study all types of latency in the system, the human response time is additionally characterized through step response tests with 11 volunteers. The step responses were obtained by tracking the position and force of the human hand in response to a change in the MR target.</p> <p>The round-trip communication latency is 40+/-10 ms over 5G, and down to 1+/-0.6 ms over Ethernet for typical throughputs. The human response time to a step change in position depends on the step magnitude, but is 485-535 ms, while the reaction time for forces is 150-200 ms. Both lags are decreased when tracking smooth motions. Thus, we demonstrate that the system is network agnostic and can achieve good teleoperation performance and secure, fast communication in appropriate network conditions. The presented tools and concepts are applicable to any high-performance teleoperation system, for example for remote surgery.</p>

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Section: Human Step Responsementioning

confidence: 97%

Section: Ice Candidatesmentioning

confidence: 99%

Section: B Human Teleoperationmentioning

confidence: 99%

Section: E Human Response Testsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evaluation of Communication and Human Response Latency for (Human) Teleoperation

Black¹,

Andjelic²,

Salcudean³

2022

Preprint

View full text Add to dashboard Cite

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Human-as-a-robot performance in mixed reality teleultrasound

Black

Salcudean

2023

Int J CARS

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Purpose In “human teleoperation” (HT), mixed reality (MR) and haptics are used to tightly couple an expert leader to a human follower [1]. To determine the feasibility of HT for teleultrasound, we quantify the ability of humans to track a position and/or force trajectory via MR cues. The human response time, precision, frequency response, and step response were characterized, and several rendering methods were compared. Methods Volunteers ( n =11) performed a series of tasks as the follower in our HT system. The tasks involved tracking pre-recorded series of motions and forces while pose and force were recorded. The volunteers then performed frequency response tests and filled out a questionnaire. Results Following force and pose simultaneously was more difficult but did not lead to significant performance degradation versus following one at a time. On average, subjects tracked positions, orientations, and forces with RMS tracking errors of mm, , N, steady-state errors of mm, N, and lags of ms, respectively. Performance decreased with input frequency, depending on the input amplitude. Conclusion Teleoperating a person through MR is a novel concept with many possible applications. However, it is unknown what performance is achievable and which approaches work best. This paper thus characterizes human tracking ability in MR HT for teleultrasound, which is important for designing future tightly coupled guidance and training systems using MR.

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