Active Touch Sensing by Multi-axial Force Measurement Using High-Resolution Tactile Sensor with Microcantilevers

In this paper, a novel capacitive tactile sensing device has proposed and demonstrated to solve coupling problem within the normal force and shear force by the unique design of electrode shape. In addition, the tactile sensor was added in the measuring capability of torsion sensing compared with traditional capacitive sensor. The perceptive unit of tactile sensor, which was consist of five sensing electrodes to detect three-axial force. The complete tactile sensor composed of a top electrode, a bottom electrode, and a spacer layer. Each capacitive sensing unit comprised a pair of the concentric-shape but different size electrodes (top electrode and bottom electrode). In the future, the proposed tactile sensor can be utilized in the wearable devices, flexible interface, and bionic robotic skins.

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A Highly-Decoupling Triangular Tactile Sensor Structure for Three-axial Force Measurement Based on Floating Comb Electrodes

CSAA/IET International Conference on Aircraft Utility Systems (AUS 2018) ◽

10.1049/cp.2018.0277 ◽

2018 ◽

Author(s):

Chenying Liu ◽

Xuesong Luo ◽

Shaoping Wang

Keyword(s):

Axial Force ◽

Force Measurement ◽

Tactile Sensor ◽

Sensor Structure

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A Coil-Based Tactile Sensor for Material Discrimination (1) and Contact Force Measurement: An Application of Multifunctional Sensing Technique

IEEJ Transactions on Sensors and Micromachines ◽

10.1541/ieejsmas.125.15 ◽

2005 ◽

Vol 125 (1) ◽

pp. 15-20

Author(s):

Zhiyu Chi ◽

Katsunori Shida

Keyword(s):

Contact Force ◽

Force Measurement ◽

Tactile Sensor ◽

Material Discrimination

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A low-cost, human-like, high-resolution, tactile sensor based on optical fibers and an image sensor

International Journal of Advanced Robotic Systems ◽

10.1177/1729881418783631 ◽

2018 ◽

Vol 15 (4) ◽

pp. 172988141878363 ◽

Cited By ~ 2

Author(s):

Utku Büyükşahin ◽

Ahmet Kırlı

Keyword(s):

High Resolution ◽

Spatial Resolution ◽

Fiber Optic ◽

Low Cost ◽

Experimental Studies ◽

Main Idea ◽

Tactile Sensor ◽

Image Sensor ◽

Sensor Design ◽

Tactile Sensors

Tactile sensors are commonly a coordinated group of receptors forming a matrix array meant to measure force or pressure similar to the human skin. Optic-based tactile sensors are flexible, sensitive, and fast; however, the human fingertip’s spatial resolution, which can be regarded as the desired spatial resolution, still could not be reached because of their bulky nature. This article proposes a novel and patented optic-based tactile sensor design, in which fiber optic cables are used to increase the number of sensory receptors per square centimeter. The proposed human-like high-resolution tactile sensor design is based on simple optics and image processing techniques, and it enables high spatial resolution and easy data acquisition at low cost. This design proposes using the change in the intesity of the light occured due to the deformation on contact/measurement surface. The main idea is using fiber optic cables as the afferents of the human physiology which can have 9 µm diameters for both delivering and receiving light beams. The variation of the light intensity enters sequent mathematical models as the input, then, the displacement, the force, and the pressure data are evaluated as the outputs. A prototype tactile sensor is manufactured with 1-mm spatial and 0.61-kPa pressure measurement resolution with 0–15.6 N/cm2 at 30 Hz sampling frequency. Experimental studies with different scenarios are conducted to demonstrate how this state-of-the-art design worked and to evaluate its performance. The overall accuracy of the first prototype, based on different scenarios, is calculated as 93%. This performance is regarded as promising for further developments and applications such as grasp control or haptics.

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Characteristics of Optical Silicone Tactile Sensor

The Journal of The Institution of Engineers, Malaysia ◽

10.54552/v76i1.38 ◽

2015 ◽

Vol 76 (1) ◽

Author(s):

Nurul Fathiah Mohamed Rosli ◽

Muhammad Azmi Ayub ◽

Roseleena Jaafan

Keyword(s):

Endoscopic Surgery ◽

Biomedical Applications ◽

Force Measurement ◽

Research Work ◽

Surface Hardness ◽

Tactile Sensor ◽

Computer Algorithm ◽

Anal Ysis ◽

Area And Perimeter ◽

Images Processing

The main objective of this research work is to anal yze the characteristics of a newly developed optical tactile sensor for sensing surface hardness. Many optical tactile sensors are bulky in size and lack of dexterity for biomedical applications. Therefore, this tactile sensor is design relative small in size and flexible for easier insertion in endoscopic surgery application. The characteristics of the tactile sensor are calibrated with respect to changes in the diameter, area and perimeter of a silicon tactile sensor subjected to normal forces applied at the point of interaction. A surface exploration computer algorithm to obtain the sensing information was developed to analyse the characteristic of the optical tactile sensor. The overall image anal ysis technique involves the following main stages: image acquisition (capturing of images), processing (thresholding, noise filtering and boundary detection ) and evaluation (force measurement). The measured forces were then compared to the actual forces to determine the accuracy of the tactile sensor’s characteristics. The results showed tluit the sensing characteristic with respect to changes in perimeter of the tactile sensor is more accurate compared to the other sensing characteristics. The outcomes of this research shows that the functionality of the developed new image anal ysis computer algorithm coupled with the silicone tactile sensor is suitable for biomedical applications such as in endoscopic surgery for measurement of tissue softness.

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A Flexible Tactile Sensor Based on Porous Graphene Sponge for Tiny Force Measurement

Volume 1: Additive Manufacturing; Bio and Sustainable Manufacturing ◽

10.1115/msec2018-6366 ◽

2018 ◽

Author(s):

Lingfeng Zhu ◽

Yancheng Wang ◽

Xin Wu ◽

Deqing Mei

Keyword(s):

Force Measurement ◽

High Sensitivity ◽

Tactile Sensor ◽

Tactile Sensors ◽

Force Detection ◽

Pressure Sensing ◽

Porous Graphene ◽

Graphene Sponge ◽

Healthcare Monitoring ◽

Working Principle

Flexible tactile sensors have been utilized for epidermal pressure sensing, motion detecting, and healthcare monitoring in robotic and biomedical applications. This paper develops a novel piezoresistive flexible tactile sensor based on porous graphene sponges. The structural design, working principle, and fabrication method of the tactile sensor are presented. The developed tactile sensor has 3 × 3 sensing units and has a spatial resolution of 3.5 mm. Then, experimental setup and characterization of this tactile sensor are conducted. Results indicated that the developed flexible tactile sensor has good linearity and features two sensitivities of 2.08 V/N and 0.68 V/N. The high sensitivity can be used for tiny force detection. Human body wearing experiments demonstrated that this sensor can be used for distributed force sensing when the hand stretches and clenches. Thus the developed tactile sensor may have great potential in the applications of intelligent robotics and healthcare monitoring.

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Axial force measurement of the bolt/nut assemblies based on the bending mode shape frequency of the protruding thread part using ultrasonic modal analysis

Measurement ◽

10.1016/j.measurement.2020.107914 ◽

2020 ◽

Vol 162 ◽

pp. 107914 ◽

Cited By ~ 2

Author(s):

Naoki Hosoya ◽

Takanori Niikura ◽

Shinji Hashimura ◽

Itsuro Kajiwara ◽

Francesco Giorgio-Serchi

Keyword(s):

Modal Analysis ◽

Axial Force ◽

Mode Shape ◽

Force Measurement ◽

Bending Mode

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Pile Model Tests Using Strain Gauge Technology

Studia Geotechnica et Mechanica ◽

10.1515/sgem-2015-0032 ◽

2015 ◽

Vol 37 (3) ◽

pp. 49-52 ◽

Cited By ~ 1

Author(s):

Adam Krasiński ◽

Tomasz Kusio

Keyword(s):

Bearing Capacity ◽

Axial Force ◽

Strain Gauge ◽

Force Measurement ◽

Ground Level ◽

Model Tests ◽

Scale Model ◽

Small Scale ◽

Pile Head ◽

Pile Model

Abstract Ordinary pile bearing capacity tests are usually carried out to determine the relationship between load and displacement of pile head. The measurement system required in such tests consists of force transducer and three or four displacement gauges. The whole system is installed at the pile head above the ground level. This approach, however, does not give us complete information about the pile-soil interaction. We can only determine the total bearing capacity of the pile, without the knowledge of its distribution into the shaft and base resistances. Much more information can be obtained by carrying out a test of instrumented pile equipped with a system for measuring the distribution of axial force along its core. In the case of pile model tests the use of such measurement is difficult due to small scale of the model. To find a suitable solution for axial force measurement, which could be applied to small scale model piles, we had to take into account the following requirements: - a linear and stable relationship between measured and physical values, - the force measurement accuracy of about 0.1 kN, - the range of measured forces up to 30 kN, - resistance of measuring gauges against aggressive counteraction of concrete mortar and against moisture, - insensitivity to pile bending, - economical factor. These requirements can be fulfilled by strain gauge sensors if an appropriate methodology is used for test preparation (Hoffmann [1]). In this paper, we focus on some aspects of the application of strain gauge sensors for model pile tests. The efficiency of the method is proved on the examples of static load tests carried out on SDP model piles acting as single piles and in a group.

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