Deep-Learning-Based Force Sensing Method for a Flexible Endovascular Surgery Robot

Abstract

Endovascular surgical robots (ESRs) are extensively researched because of their potential to minimize surgeons’ radiation exposure. However, during the surgical operation, it is difficult for ESR to achieve the same flexibility in manipulating the soft catheter and the slender guidewire as human fingers. The flexibility of ESR can be enhanced by incorporating a soft gripper, but the nonlinear deformation of soft material presents challenges in sensing and controlling the force. To address these issues, this study proposes a deep learning-based force sensing method that enables the flexible ESR to measure the surgical force and torque. The proposed deep learning model consists of multiple-layer Long Short-Term Memory (LSTM) modules and is trained using the robot’s motion and soft gripper deformation datasets. The well-trained LSTM model can predict the operationing force and torque in real time. The contrast experiments with other models demonstrate that our robot exhibits higher force measurement accuracy. Furthermore, a force control strategy is proposed for the application of LSTMbased ESR. In the force control strategy, the robot is encouraged to mimic the dexterity of surgeon’s fingers and to maintain the force within a safe range. Finally, the proposed strategy is compared with other strategies in vascular phantom experiments and is proven to effectively enhance the safety and efficiency of surgical operations.