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A monolithic approach to fabricating low-cost, millimeter-scale multi-axis force sensors for minimally-invasive surgery

Joshua B. Gafford, Samuel B. Kesner, Alperen Değirmenci, Robert J. Wood, Robert D. Howe, Conor J. Walsh

Year
2014
Citations
29

Abstract

In this paper we have rapidly prototyped customized, highly-sensitive, mm-scale multi-axis force sensors for medical applications. Using a composite laminate batch fabrication process with biocompatible constituent materials, we have fabricated a fully-integrated, 10×10 mm three-axis force sensor with up to 5 V/N sensitivity and RMS noise on the order of ~1.6 mN, operational over a range of -500 to 500 mN in the x- and y-axes, and -2.5 to 2.5 N in the z-axis. Custom foil-based strain sensors were fabricated in parallel with the mechanical structure, obviating the need for post-manufacturing alignment and assembly. The sensor and its custom-fabricated signal conditioning circuitry fit within a 1×1×2 cm volume to realize a fully-integrated force transduction platform with potential haptics and control applications in minimally-invasive surgical tools. The form factor, biocompatibility, and cost of the sensor and signal conditioning makes this method ideal for rapid-prototyping low-cost, mm-scale distal force sensors. Sensor performance is validated in a simulated tissue palpation task using a robotic master-slave platform.

Keywords

Signal conditioningFabricationHaptic technologyMaterials scienceSIGNAL (programming language)Biomedical engineeringGauge factorComputer scienceSimulationEngineering

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