Vision-Based Tactile Sensor Mechanism for the Estimation of Contact Position and Force Distribution Using Deep Learning

Kakani, Vijay; Cui, Xuenan; Ma, Mingjie; Kim, Hakil

doi:10.3390/s21051920

Cited by 33 publications

(21 citation statements)

References 38 publications

(36 reference statements)

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“…The CNN algorithm is a subset of deep neural networks and deep learning paradigms [ 22 ], and has proven its effectiveness as an image, speech recognition, face detection, futures extraction algorithm. The novel research confirms that CNNs have advantages in series forecasting, a data-driven approach for diagnostic and fault classification of various industrial processes and applications [ 23 , 24 , 25 , 26 , 27 ].…”

Section: Introductionsupporting

confidence: 62%

Automated Inorganic Pigment Classification in Plastic Material Using Terahertz Spectroscopy

Sarjaš

Pongrac

Gleich

2021

Sensors

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This paper presents an automatic classification of plastic material’s inorganic pigment using terahertz spectroscopy and convolutional neural networks (CNN). The plastic materials were placed between the THz transmitter and receiver, and the acquired THz signals were classified using a supervised learning approach. A THz frequency band between 0.1–1.2 THz produced a one-dimensional (1D) vector that is almost impossible to classify directly using supervised learning. This paper proposes a novel pre-processing of 1D THz data that transforms 1D data into 2D data, which are processed efficiently using a convolutional neural network. The proposed pre-processing algorithm consists of four steps: peak detection, envelope extraction, and a down-sampling procedure. The last main step introduces the windowing with spectrum dilatation that reorders 1D data into 2D data that can be considered as an image. The spectrum dilation techniques ensure the classifier’s robustness by suppressing measurement bias, reducing the complexity of the THz dataset with negligible loss of accuracy, and speeding up the network classification. The experimental results showed that the proposed approach achieved high accuracy using a CNN classifier, and outperforms 1D classification of THz data using support vector machine, naive Bayes, and other popular classification algorithms.

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Section: Introductionsupporting

confidence: 62%

Automated Inorganic Pigment Classification in Plastic Material Using Terahertz Spectroscopy

Sarjaš

Pongrac

Gleich

2021

Sensors

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“…Owing to the high sensitivity realized with the optical scattering interference, the proposed approach can enable the sensing of physical contacts with high spatial resolution of few tens of micrometers. Thus, it outperforms previous electrical and optical approaches used in this field of study 33 – 36 , although the precision is slightly lower than that of the state-of-the-art measurements, such as speckle interferometry, holography, and projection techniques 42 , 44 , 47 , 48 . Higher spatial resolution and greater precision of measurement of the indentation can be achieved by using a larger number of training samples.…”

Section: Discussionmentioning

confidence: 85%

“…A previous approach to achieve high spatial sensing capability was based on the integration of a large number of sensors to form a sensor matrix with numerous wire connections; however, this usually incurs high integration complexity. Although a vision-based tactile sensing approach using a marker displacement is easy to manufacture 36 , the spatial resolution is limited, and it is difficult to simultaneously detect other parameters such as temperature.…”

Section: Introductionmentioning

confidence: 99%

Speckle-based high-resolution multimodal soft sensing

Shimadera

Kitagawa

Koyo

et al. 2022

Sci Rep

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Skin-like soft sensors are key components for human–machine interfaces; however, the simultaneous sensing of several types of stimuli remains challenging because large-scale sensor integration is required with numerous wire connections. We propose an optical high-resolution multimodal sensing approach, which does not require integrating multiple sensors. This approach is based on the combination of an optical scattering phenomenon, which can encode the information of various stimuli as a speckle pattern, and a decoding technique using deep learning. We demonstrate the simultaneous sensing of three different physical quantities—contact force, contact location, and temperature—with a single soft material. Another unique capability of the proposed approach is spatially continuous sensing with an ultrahigh resolution of few tens of micrometers, in contrast to previous multimodal sensing approaches. Furthermore, a haptic soft device is presented for a human–machine interface. Our approach encourages the development of high-performance smart skin-like sensors.

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“…In such a configuration, all the fibers will exhibit levels of intensity loss. With proper non-linear calibration, i.e., learning-based rate-dependent methods [ 38 ], a mapping between states of the intensity loss in the four fibers and the position and magnitude of the external force can be obtained. Since in this experiment only one fiber was utilized, obtaining such calibration was not possible.…”

Section: Resultsmentioning

confidence: 99%

Optical Fiber Array Sensor for Force Estimation and Localization in TAVI Procedure: Design, Modeling, Analysis and Validation

Bandari

Dargahi

Packirisamy

2021

Sensors

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Transcatheter aortic valve implantation has shown superior clinical outcomes compared to open aortic valve replacement surgery. The loss of the natural sense of touch, inherited from its minimally invasive nature, could lead to misplacement of the valve in the aortic annulus. In this study, a cylindrical optical fiber sensor is proposed to be integrated with valve delivery catheters. The proposed sensor works based on intensity modulation principle and is capable of measuring and localizing lateral force. The proposed sensor was constituted of an array of optical fibers embedded on a rigid substrate and covered by a flexible shell. The optical fibers were modeled as Euler–Bernoulli beams with both-end fixed boundary conditions. To study the sensing principle, a parametric finite element model of the sensor with lateral point loads was developed and the deflection of the optical fibers, as the determinant of light intensity modulation was analyzed. Moreover, the sensor was fabricated, and a set of experiments were performed to study the performance of the sensor in lateral force measurement and localization. The results showed that the transmitted light intensity decreased up to 24% for an external force of 1 N. Additionally, the results showed the same trend between the simulation predictions and experimental results. The proposed sensor was sensitive to the magnitude and position of the external force which shows its capability for lateral force measurement and localization.

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Vision-Based Tactile Sensor Mechanism for the Estimation of Contact Position and Force Distribution Using Deep Learning

Cited by 33 publications

References 38 publications

Automated Inorganic Pigment Classification in Plastic Material Using Terahertz Spectroscopy

Automated Inorganic Pigment Classification in Plastic Material Using Terahertz Spectroscopy

Speckle-based high-resolution multimodal soft sensing

Optical Fiber Array Sensor for Force Estimation and Localization in TAVI Procedure: Design, Modeling, Analysis and Validation

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