Closed-Loop Control of a Magnetically Actuated Fiber-Coupled Laser for Computer-Assisted Laser Microsurgery

TL;DR

This paper introduces a novel closed-loop magnetic control system for fiber-coupled laser micro-surgery, enabling precise, automated laser scanning through electromagnetic feedback, improving surgical accuracy and automation.

Contribution

It presents the first closed-loop magnetic control system for fiber laser micro-surgery, integrating feedback from a photodetector for high-speed, accurate laser tip positioning.

Findings

Simulation results match experimental data.

High-speed laser scanning achieved.

Enhanced control accuracy demonstrated.

Abstract

Patient outcomes in the medical field are improving through the use and incorporation of robotics technology and laser physics, e.g., the use of optical fibers and lasers in micro-surgery. This paper describes the design and implementation of a new optical fiber laser micro-surgery system, one that is the first to use closed-loop feedback control. In this computerassisted laser scanning tool the laser beam is controlled by four magnetic actuators. After attaching permanent magnets to the free end of the optical fiber, it is the control of these four magnets that produces an accurate laser scanning system, one suited to micro-surgery applications. The interaction between the electromagnetic fields generated by the external magnetic coils and the flux of the internal permanent magnets, produces the control torques required to produce the desired movement of the optic fiber. The tracking error of the optic fiber is compensated for by using a photo-detector sensor as the feedback transducer in the control system. The magnetic torque bends the optical fiber and the feedback from the photodetector gives automated control and high-speed laser scanning of the fiber tip. The simulation and the experimental results are accurate and are co-related.