Soft curvature sensors for joint angle proprioception

Kramer, Rebecca K.; Majidi, Carmel; Sahai, Ranjana; Wood, Robert J.

doi:10.1109/iros.2011.6094701

Cited by 140 publications

(37 citation statements)

References 20 publications

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“…The actuator-spring designs developed in the current study can be implemented with future modifications of the finger exercise device, which will include reducing the size of the spooling actuation system, scaling up from a single finger device to a full hand rehabilitation device, including sensors to provide force and joint position feedback [19], and implementing safety mechanisms to protect repaired finger from excessive mechanical loading. In addition, the device should have an output display that provides information on time, joint angles, and force applied so as to allow therapists and surgeons to know the details of the CPM intervention and the corresponding results.…”

Section: Discussionmentioning

confidence: 99%

Cable-Driven Finger Exercise Device With Extension Return Springs for Recreating Standard Therapy Exercises

Yeow

Baisch

Talbot

et al. 2013

Journal of Medical Devices

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Finger therapy exercises, which include table top, proximal-interphalangeal blocking, straight fist, distal-interphalangeal blocking, hook-fist, and fist exercises, are important for maintaining hand mobility and preventing development of tendon adhesions in postoperative hand-injury patients. Continuous passive motion devices act as an adjunct to the therapist in performing therapy exercises on patients; however, current devices are unable to recreate these exercises well. The current study aimed to design and evaluate a finger exercise device that reproduces the therapy exercises by adopting a cable-actuated flexion and spring-return extension mechanism. The device comprises of phalanx interface attachments, connected by palmar-side cables to spooling actuators and linked by dorsal-side extension springs to provide passive return. Two designs were tested whereby the springs had similar (design 1) or different stiffnesses (design 2). The device was donned onto a model hand and actuated into the desired therapy postures. Our findings indicated that design 1 was able to recreate table top, straight fist, and fist exercises while design 2 was capable of further replicating distal-interphalangeal blocking, proximal-interphalangeal blocking, and hook-fist exercises. This work demonstrated the possibility of replicating finger therapy exercises using a cable-actuated flexion and spring-return extension design, which lays the groundwork for prospective finger exercise devices that can be donned on patients to assess the efficacy in postoperative joint rehabilitation.

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Section: Discussionmentioning

confidence: 99%

Cable-Driven Finger Exercise Device With Extension Return Springs for Recreating Standard Therapy Exercises

Yeow

Baisch

Talbot

et al. 2013

Journal of Medical Devices

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“…Additionally, the current work is able to measure curvature without knowing the geometry of, or even requiring, an underlying host. This is in contrast to previous work which used deflection of a mechanical joint to induce strain in a liquid metal sensor, and required re-calibration on a per-host basis [14,15]. Finally, the current work expands upon the previous example of multi-layer liquid metal sensors by placing strain gauges in parallel, rather than orthogonally [23].…”

Section: Introductionmentioning

confidence: 93%

“…By combining two of these strain/curvature sensors, we demonstrate a device which can differentiate between positive curvature, negative curvature and strain. Individually, each element of the devices in this paper behaves according to the theory described in [14] and [15], which we revisit in our theoretical discussion below. In previously published devices, uniaxial strain and bending produced the same sensor output, resulting in ambiguous measurements.…”

Section: Introductionmentioning

confidence: 99%

“…Elastomer-based sensors with encapsulated liquid metals such as those described in this work are well represented in the literature. Previously reported soft sensory devices based on elastomers substrates include joint angle and curvature sensors [14,15], pressure sensors [16,17] capacitance-based multi-element force sensors [18,19], liquid-metal/conductive fluid hybrid strain sensors [20,21,22], and multi-mode resistance-based devices measuring in-plane strain and out-of-plane pressure [23].…”

Section: Introductionmentioning

confidence: 99%

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Multi-mode strain and curvature sensors for soft robotic applications

White

Case

Kramer

2017

Sensors and Actuators A: Physical

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In this paper we describe the fabrication and testing of elastomer-based sensors capable of measuring both uniaxial strain and curvature. These sensors were fabricated from Sylgard 184, which is a transparent silicone elastomer. We created microchannels directly in silicone elastomer substrates using a laser to ablate material. The sensing element was an alloy of gallium and indium, which is liquid at room temperature, contained within the laser-created microchannels. As the substrate deformed, the microchannel deformed within it, resulting in a measurable change in electrical resistance. By fabricating two matching resistive strain-sensing elements on opposite sides of the sensor, we were able to unambiguously measure uniaxial strain and curvature by observing the common mode and differential mode changes in resistance, respectively. There was very little coupling between modes, demonstrating the utility of the differential sensor design. We characterized the sensor in terms of its response to strain and curvature, its noise, and its stability over time. We believe that this type of sensor has application in soft sensory skins and can observe pose in soft robotic systems.

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“…Several groups have recently reported artificial tactile skins for applications in macroelectronics, soft robotics, prosthetics, and bio-inspired electronics. These "soft" pressure sensing technologies rely on microstructured elastomers 1,2 or composite polymers [3][4][5] integrated in resistive or capacitive devices, ferroelectric sensors, 6 liquid metal microfluidics, 7 optical waveguides 8,9 or inorganic semiconductor nanomembranes printed on elastomeric substrate. 10 In all cases, the soft polymer is implemented as the carrier or the sensitive material and is usually a homogeneous elastomer with an elastic modulus in the 10 s-1000 s kPa range.…”

mentioning

confidence: 99%

Extremely robust and conformable capacitive pressure sensors based on flexible polyurethane foams and stretchable metallization

Vandeparre

Watson

Lacour

2013

Applied Physics Letters

126

111

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Microfabricated capacitive sensors prepared with elastomeric foam dielectric films and stretchable metallic electrodes display robustness to extreme conditions including stretching and tissue-like folding and autoclaving. The open cellular structure of the elastomeric foam leads to significant increase of the capacitance upon compression of the dielectric membrane. The sensor sensitivity can be adjusted locally with the foam density to detect normal pressure in the 1 kPa to 100 kPa range. Such pressure transducers will find applications in interfaces between the body and support surfaces such as mattresses, joysticks or prosthetic sockets, in artificial skins and wearable robotics.

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Soft curvature sensors for joint angle proprioception

Cited by 140 publications

References 20 publications

Cable-Driven Finger Exercise Device With Extension Return Springs for Recreating Standard Therapy Exercises

Cable-Driven Finger Exercise Device With Extension Return Springs for Recreating Standard Therapy Exercises

Multi-mode strain and curvature sensors for soft robotic applications

Extremely robust and conformable capacitive pressure sensors based on flexible polyurethane foams and stretchable metallization

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