A Novel Tactile Force Probe for Tissue Stiffness Classification

TL;DR

This paper introduces a new tactile sensor capable of measuring both force and tissue stiffness, enabling improved object discrimination for robotic and medical applications.

Contribution

A novel tactile force sensor design that measures tissue stiffness and applied force using induced voltage changes in coils, enhancing robotic and surgical tools.

Findings

Successfully discriminated between polyurethane, silicon rubber, and paraffin gel.

Capable of measuring both force and stiffness simultaneously.

Potential applications in robotic manipulation and minimally invasive surgery.

Abstract

In this study, we have proposed a new type of tactile sensor that is capable of detecting the stiffness of soft objects. The sensor consists of a brass cylinder with an axial bore. An iron core can easily move inside the bore. Three peripheral bobbins were machined in the cylinder around which three coils have been wound. One of the coils was excited with an alternating current which caused a voltage to be induced in two other coils. A return spring was used to return the core to its initial position after it has been moved. The sensor was pressed against the surface of the object whose stiffness was going to be measured. The position of the core in this state was depended on the stiffness of the given object and the spring constant and was measured by measuring the change in the induced voltage in secondary coils. The proposed sensor was capable of measuring two contact parameters namely the applied force and the stiffness of the object. Using the data of this sensor, three different objects, made of polyurethane, silicon rubber and paraffin gel were discriminated. Thus, this sensor could be used in robot hands and minimally invasive surgery tools to improve their operation.