An optical contact force sensor for tactile sensing based on specklegram detection from concatenated multimode fibers

An optical contact force sensor based on specklegram detection was proposed and validated for tactile sensing in this research. The specklegrams from different multimode fiber (MMF) based structures were firstly analyzed and compared in detail. Two of the structures based on the concatenation of MMF and few mode fiber (FMF) were selected. In the experiment, only the section of MMF is housed in a specially designed sensor head by 3D printing and the FMF section is used to lead the light out to the camera. The concatenated fiber structure enables the sensitive response to the applied force and shows insensitivity to the disturbance along the light lead-out part. With a contact force applying to the sensor head, bending of the MMF could be induced, which results in a deformed specklegram. In this way, the zero-mean normalized cross-correlation coefficient of the fiber specklegrams goes down with the increase of the contact force. For the selected fiber structure with different parameters, different sensitivity and different measurement ranges of force are realized, of which the largest linear measurement range of force is 0-23 N. Compared with only adopting MMF, the proposed scheme presents better stability together with a large measurement range and the flexibly adjusted sensitivity by changing the parameters of the fiber or the sensor head.

Automated summary

An optical contact force sensor based on specklegram detection was proposed and validated in this study, enabling sensitive response to applied force and insensitivity to light disturbance. By changing parameters of the fiber or sensor head, the sensitivity and measurement range of force can be flexibly adjusted, presenting better stability and a large measurement range compared to using only MMF.