Integrated Piezoresistive Force and Position Detection Sensors for Micro-Handling Applications

Wei, Jia; Porta, Marcello; Tichem, Marcel; Staufer, U.; Sarro, P.M.

doi:10.1109/jmems.2013.2259142

Cited by 19 publications

(6 citation statements)

References 26 publications

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“…With an embedded force sensing unit, the system is capable of ensuring the threshold force is never surpassed and in the case of a biological medium, the object being manipulated retains its properties and viability. Multiple force sensing methods have been shown for micromanipulation or microrobotic applications, such as piezoelectric/piezoresistive [ 21 , 22 , 23 , 24 ], atomic force microscope (AFM) [ 25 , 26 ], vision-based [ 11 , 27 ], and capacitive [ 28 , 29 ]. From these methods, a vision-based force sensor modality is selected for use here since it is able to overcome many of the drawbacks other sensors, such as high costs and difficult integration with micromanipulation systems (AFM sensors), complicated circuitry (capacitive sensors), and temperature sensitivity (piezoresistive sensors).…”

Section: Introductionmentioning

confidence: 99%

Towards a Comprehensive and Robust Micromanipulation System with Force-Sensing and VR Capabilities

et al. 2021

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In this modern world, with the increase of complexity of many technologies, especially in the micro and nanoscale, the field of robotic manipulation has tremendously grown. Microrobots and other complex microscale systems are often to laborious to fabricate using standard microfabrication techniques, therefore there is a trend towards fabricating them in parts then assembling them together, mainly using micromanipulation tools. Here, a comprehensive and robust micromanipulation platform is presented, in which four micromanipulators can be used simultaneously to perform complex tasks, providing the user with an intuitive environment. The system utilizes a vision-based force sensor to aid with manipulation tasks and it provides a safe environment for biomanipulation. Lastly, virtual reality (VR) was incorporated into the system, allowing the user to control the probes from a more intuitive standpoint and providing an immersive platform for the future of micromanipulation.

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Section: Introductionmentioning

confidence: 99%

Towards a Comprehensive and Robust Micromanipulation System with Force-Sensing and VR Capabilities

et al. 2021

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“…Traditional force detection methods often use force sensors (4) . However, the measurement range of the force sensor is limited.…”

Section: Introductionmentioning

confidence: 99%

Dynamics Identification and Contact Force Estimation of Multi DoF Robot Based on Base Frame Force Sensor

Fukutoku

Murakami

2021

The Proceedings of the 9th IIAE International Conference on Industrial Application Engineering 2020

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External force detection system plays an important role for robots to operate in the human living environment. Force information determines the interaction between the robot and the environment. However, there are many restrictions on the use of force sensors. Many force sensors are required for wide range contact detection. The force sensor-less method that uses current and angle information is difficult to apply for high reduction ratio mechanisms. In this paper, we propose a method for estimating contact force using one force sensor implemented in the base frame. It is necessary to identify the robot dynamics in order to estimate the contact force. Only the base frame force sensor and encoders are used to identify the dynamics. Therefore, it is very easy to apply. In addition, since it is not affected by joint friction, it can be applied to high reduction ratio mechanisms. The proposed contact force estimation method has a sensitivity for the entire robots. Therefore, contact detection is possible no matter where the force is applied to the robot. The effectiveness of the dynamics identification and the contact force estimation is verified experimentally.

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“…Resistive MEMS sensors are used in various applications such as strain gauges, pressure sensors, acceleration sensors, and force sensors. (1)(2)(3)(4)(5) For the implementation of a highprecision sensor interface circuit for these high-performance resistive sensors, low noise, low offset, and high input impedance are required. There are two general architectures for a resistive sensor interface circuit: a current-feedback instrumentation amplifier (CFIA) and a 3-opamp voltage feedback instrumentation amplifier (IA).…”

Section: Introductionmentioning

confidence: 99%

Chopper-stabilized Multipath Instrumentation Amplifier with Output Voltage Offset Compensation Using R-2R Digital-to-Analog Converter

Heo¹,

Kim²,

You³

et al. 2021

Sensors and Materials

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This paper presents a 3-opamp resistive bridge sensor analog front-end (AFE) integrated circuit (IC) with offset voltage compensation using an R-2R digital-to-analog converter (DAC). The proposed IC is implemented with a 3-opamp instrumentation amplifier (IA) to achieve high gain, high input impedance, and linearity. The two amplifiers in the first stage are multipath amplifiers with a chopper stabilization technique and ripple reduction loop (RRL). The chopper stabilization technique reduces 1/f flicker noise and DC offset, and the RRL mitigates the output ripple voltage resulting from the chopper stabilization technique. The multipath amplifier scheme compensates the notch characteristic in the frequency response caused by the RRL. A fully differential amplifier with a class-AB output stage is used in the second stage to achieve power efficiency. The 12-bit R-2R DAC is implemented to compensate the offset of the secondstage output of the IA. The IA gain can be controlled from 12 to 48 dB using 2-bit and 3-bit programmable feedback resistor arrays in the first and second stages, respectively. The proposed IC is designed with a 0.18 μm complementary metal-oxide-semiconductor (CMOS) process and has an active area of 7.2 mm 2 . The simulated input-referred noise is 36.7 nV/√Hz at a frequency of 1 Hz and the simulated input offset voltage is 2.2 μV.

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Integrated Piezoresistive Force and Position Detection Sensors for Micro-Handling Applications

Cited by 19 publications

References 26 publications

Towards a Comprehensive and Robust Micromanipulation System with Force-Sensing and VR Capabilities

Towards a Comprehensive and Robust Micromanipulation System with Force-Sensing and VR Capabilities

Dynamics Identification and Contact Force Estimation of Multi DoF Robot Based on Base Frame Force Sensor

Chopper-stabilized Multipath Instrumentation Amplifier with Output Voltage Offset Compensation Using R-2R Digital-to-Analog Converter

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