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Main Authors: Annamraju, Srikar, Chen, Yuxi, Lim, Jooyoung, Kim, Inki
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.20373
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author Annamraju, Srikar
Chen, Yuxi
Lim, Jooyoung
Kim, Inki
author_facet Annamraju, Srikar
Chen, Yuxi
Lim, Jooyoung
Kim, Inki
contents Goal: A limitation in robotic surgery is the lack of force feedback, due to challenges in suitable sensing techniques. To enhance the perception of the surgeons and precise force rendering, estimation of these forces along with tissue deformation level is presented here. Methods: An experimental test bed is built for studying the interaction, and the forces are estimated from the raw data. Since tissue deformation and stiffness are non-linearly related, they are independently computed for enhanced reliability. A Convolutional Neural Network (CNN) based vision model is deployed, and both classification and regression models are developed. Results: The forces applied on the tissue are estimated, and the tissue is classified based on its deformation. The exact deformation of the tissue is also computed. Conclusions: The surgeons can render precise forces and detect tumors using the proposed method. The rarely discussed efficacy of computing the deformation level is also demonstrated.
format Preprint
id arxiv_https___arxiv_org_abs_2504_20373
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Estimation of Tissue Deformation and Interactive Force in Robotic Surgery through Vision-based Learning
Annamraju, Srikar
Chen, Yuxi
Lim, Jooyoung
Kim, Inki
Systems and Control
Goal: A limitation in robotic surgery is the lack of force feedback, due to challenges in suitable sensing techniques. To enhance the perception of the surgeons and precise force rendering, estimation of these forces along with tissue deformation level is presented here. Methods: An experimental test bed is built for studying the interaction, and the forces are estimated from the raw data. Since tissue deformation and stiffness are non-linearly related, they are independently computed for enhanced reliability. A Convolutional Neural Network (CNN) based vision model is deployed, and both classification and regression models are developed. Results: The forces applied on the tissue are estimated, and the tissue is classified based on its deformation. The exact deformation of the tissue is also computed. Conclusions: The surgeons can render precise forces and detect tumors using the proposed method. The rarely discussed efficacy of computing the deformation level is also demonstrated.
title Estimation of Tissue Deformation and Interactive Force in Robotic Surgery through Vision-based Learning
topic Systems and Control
url https://arxiv.org/abs/2504.20373