Abstract
After each robot end tool replacement, tool center point (TCP) calibration must be performed to achieve precise control of the end tool. This process is also essential for robot-assisted puncture surgery. The purpose of this article is to solve the problems of poor accuracy stability and strong operational dependence in traditional TCP calibration methods and to propose a TCP calibration method that is more suitable for a physician. This paper designs a special binocular vision system and proposes a vision-based TCP calibration algorithm that simultaneously identifies tool center point position (TCPP) and tool center point frame (TCPF). An accuracy test experiment proves that the designed special binocular system has a positioning accuracy of ±0.05 mm. Experimental research shows that the magnitude of the robot configuration set is a key factor affecting the accuracy of TCPP. Accuracy of TCPF is not sensitive to the robot configuration set. Comparison experiments show that the proposed TCP calibration method reduces the time consumption by 82%, improves the accuracy of TCPP by 65% and improves the accuracy of TCPF by 52% compared to the traditional method. Therefore, the method proposed in this article has higher accuracy, better stability, less time consumption and less dependence on the operations than traditional methods, which has a positive effect on the clinical application of high-precision robot-assisted puncture surgery.
Highlights
Introduction for RobotAssisted Puncture Surgery.Robot-assisted needle insertion technology can improve the accuracy and security of many minimally invasive percutaneous surgeries, such as biopsy and brachytherapy.Usually, a robot-assisted needle insertion system mainly includes a lesion navigation system and a robot [1]
An important reason is the inaccuracy of the tool center point (TCP) which is often described as the tool center point position (TCPP)
We considered tool center point frame (TCPF) calibration as the direction calibration problem of straight homogeneous generalized cylinders (SHGC) [26,27,28,29,30]
Summary
The experiment system is composed of a collaborative robot, binocular vision system and PC software. In this system, we adopt a 6 DOF collaborative robot offered by UNIVERSAL ROBOTS Co., Ltd. The binocular vision system is formed by two industrial CCD cameras offered by DAHENG IMAGING. The system applies diffuse bright-field back light illumination to improve the image contrast, thereby improving the measurement accuracy. This illumination design can help the camera to obtain a clear image with a small aperture. While theSystem systemDesign is working, the operator manually jogs the robotic arm to place the
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