A liquid lens-based optical sensor for tactile sensing

Yang, Hui; Fu, Jian; Cao, Rong; Liu, Jiaqi; Wang, Lihui

doi:10.1088/1361-665x/ac4d64

Cited by 9 publications

(8 citation statements)

References 44 publications

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“…A typical working principle of a non-camera-based optical tactile sensor utilizes the detection of a change in light intensity by a photodetector [7] when a contact force occurs, which allows tactile information to be extracted from these changes in measured intensity. Tactile optical-based sensors take a variety of shapes and use different materials such as elastomers, optical fibers [22], photodiodes [7], and liquid lenses [23].…”

Section: Introductionmentioning

confidence: 99%

“…3) that can estimate 3D point displacements and 3D point forces by interpreting the measured angle and intensity of light (i.e., the light vector) arriving at an optical sensor; thus, we named it the LiVec sensor. Compared with other existing optical-based tactile sensors [9], [23], [27], [28], the LiVec sensor has a simple structure consisting of a soft deformable skin, LEDs, and a light angle and intensity sensor. All the sensing elements are combined onto a singular printed circuit board (PCB), giving it the potential for substantial volume reduction compared to other existing tactile sensors [7] [10], [21], [25], [29]- [31] [32] and significantly reducing the complexity of the manufacturing process.…”

Section: Introductionmentioning

confidence: 99%

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A Tactile Sensing Concept for 3D Displacement and 3D Force Measurement using Light Angle and Intensity Sensing

Leslie¹,

Bulens²,

Ulloa³

et al. 2023

Preprint

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<p>This paper proposes an optical-based tactile sensor design concept, which uses a light angle and intensity sensor to infer force and displacement from deformations of a silicone pillar. The proposed design uses a simple, low?cost fabrication method with an overall small-scale form factor. The sensor can measure 3D displacement, 3D force, and vibration. The overall displacement estimation error (mean ± SD) in the X, Y, and Z axes was 40.2 µm ± 34.8 µm, 4.0 µm ± 55.3 µm and 13.3 µm ± 11.8 µm, respectively, over a full-scale lateral displacement of 1 mm radius in X and Y and 2.2 mm compression in Z. The overall force estimation error (mean ± SD) was 38.3 ± 29.6 mN, 40.1 ± 29.4 mN and 0.074 ±61.9 mN for a full-scale force of approximately 2 N in X or Y, and 6 N in Z. Sensitivity to vibrations in the range of 10-950 Hz was also evaluated showing good sensitivity over this entire range. This new sensing approach could be of benefit in robotic manipulation applications, as it could be easily arrayed and/or integrated into the fingers of a robotic gripper to sense slip events and measure load and grip forces and torques. </p>

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Tactile Sensing Concept for 3D Displacement and 3D Force Measurement using Light Angle and Intensity Sensing

Leslie¹,

Bulens²,

Ulloa³

et al. 2023

Preprint

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show abstract

“…Based on the different development principles, the existing tactile sensors are mainly divided into capacitive 7 , piezoresistive 8 , piezoelectric 9 , triboelectric 10 , and optical 11,12 . Among them, the optical tactile sensor has the advantages of no electromagnetic interference, simple structure, low power consumption, wide dynamic range, and high resolution 13,14 .…”

Section: Introductionmentioning

confidence: 99%

Research on a flexible optical tactile sensor based on a liquid lens structure

Hu,

Yang,

Wang

et al. 2023

Advanced Sensor Systems and Applications XIII

Self Cite

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“…Therefore, according to this, different with existed optical conduction‐based tactile sensors, the output of our tactile sensor increase with the increase of external contact force. However, in our previous work, we only preliminarily explored the feasibility of the sensing method based on the liquid lens, so the proposed sensor has many drawbacks in sensing structure, [ 38 ] which are embodied in large dimension, small measurement range, and low resolution (as shown in Table 1 ). Moreover, the proposed sensor contains a big and rigid liquid vessel and many optics components, which makes the sensor becomes a bulky integration.…”

Section: Introductionmentioning

confidence: 99%

“…To reduce the interference caused by optical loss, in our previous work, we presented an optical tactile sensor based on the principle of the liquid lens. [38] The liquid lens as a kind of variable-focus lens has many advantages, such as simple structure, fast response, and low optical loss, [39−41] and thus has been applied to the optical imaging field. [42,43] Moreover, the liquid lens has the characteristic that its focal length can decrease with the increase of liquid volume in the lens, which makes the incident light converge toward a center point.…”

Section: Introductionmentioning

confidence: 99%

Liquid Lens‐Based Optical Tactile Sensor with a Touch‐Sensing Separable Structure

Yang

Liu

et al. 2022

Adv Materials Inter

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Optical tactile sensing plays an important role in the tactile sensing field, due to its high sensitivity, fast response, and prominent interference immunity. Herein, based on the liquid lens, a low‐cost optical tactile sensor with a touch‐sensing separable structure is designed and fabricated, and it contains a touch unit and an optics sensing unit. The touch unit is a chamber structure with good integration, and the optics sensing unit is designed with a liquid‐membrane structure. Different from the existed optical tactile sensors, the principle of the proposed sensor is that the focal length of the optics sensing unit is changed with an external contact force, and then the directional light propagation direction produces change, which affects the perceived light intensity of the silicon photocell. From the sensing performance test results, this tactile sensor has good statics and dynamics performance, which embodies in the rapid response time (about 0.048 s), stable output, high sensitivity (the max sensitivity is about 7.1338 V/N), and resolution (0.01 N), low hysteresis ratio (less than 6.5%), and good linearity (R2 ≈ 0.98). In addition, some application experiments are conducted and the results demonstrate the application feasibility of the proposed sensor in health monitoring and multichannel sensing.

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A liquid lens-based optical sensor for tactile sensing

Cited by 9 publications

References 44 publications

A Tactile Sensing Concept for 3D Displacement and 3D Force Measurement using Light Angle and Intensity Sensing

A Tactile Sensing Concept for 3D Displacement and 3D Force Measurement using Light Angle and Intensity Sensing

Research on a flexible optical tactile sensor based on a liquid lens structure

Liquid Lens‐Based Optical Tactile Sensor with a Touch‐Sensing Separable Structure

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