Self healable neuromorphic memtransistor elements for decentralized sensory signal processing in robotics

Rohit Abraham John; Naveen Tiwari; Muhammad Iszaki Bin Patdillah; Mohit Rameshchandra Kulkarni; Nidhi Tiwari; Joydeep Basu; Sumon Kumar Bose; null Ankit; Chan Jun Yu; Amoolya Nirmal; Sujaya Kumar Vishwanath; Chiara Bartolozzi; Arindam Basu; Nripan Mathews

doi:10.1038/s41467-020-17870-6

Self healable neuromorphic memtransistor elements for decentralized sensory signal processing in robotics

Rohit Abraham John, Naveen Tiwari, Muhammad Iszaki Bin Patdillah, Mohit Rameshchandra Kulkarni, Nidhi Tiwari, Joydeep Basu, Sumon Kumar Bose, Ankit, Chan Jun Yu, Amoolya Nirmal, Sujaya Kumar Vishwanath, Chiara Bartolozzi, Arindam Basu^*, Nripan Mathews^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

90 Citations (Scopus)

44 Downloads (CityUHK Scholars)

Abstract

Sensory information processing in robot skins currently rely on a centralized approach where signal transduction (on the body) is separated from centralized computation and decision-making, requiring the transfer of large amounts of data from periphery to central processors, at the cost of wiring, latency, fault tolerance and robustness. We envision a decentralized approach where intelligence is embedded in the sensing nodes, using a unique neuromorphic methodology to extract relevant information in robotic skins. Here we specifically address pain perception and the association of nociception with tactile perception to trigger the escape reflex in a sensorized robotic arm. The proposed system comprises self-healable materials and memtransistors as enabling technologies for the implementation of neuromorphic nociceptors, spiking local associative learning and communication. Configuring memtransistors as gated-threshold and -memristive switches, the demonstrated system features in-memory edge computing with minimal hardware circuitry and wiring, and enhanced fault tolerance and robustness.

Original language	English
Article number	4030
Journal	Nature Communications
Volume	11
Issue number	1
Online published	12 Aug 2020
DOIs	https://doi.org/10.1038/s41467-020-17870-6
Publication status	Published - 2020
Externally published	Yes

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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John, R. A., Tiwari, N., Patdillah, M. I. B., Kulkarni, M. R., Tiwari, N., Basu, J., Bose, S. K., Ankit, Yu, C. J., Nirmal, A., Vishwanath, S. K., Bartolozzi, C., Basu, A., & Mathews, N. (2020). Self healable neuromorphic memtransistor elements for decentralized sensory signal processing in robotics. Nature Communications, 11(1), Article 4030. https://doi.org/10.1038/s41467-020-17870-6

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title = "Self healable neuromorphic memtransistor elements for decentralized sensory signal processing in robotics",

abstract = "Sensory information processing in robot skins currently rely on a centralized approach where signal transduction (on the body) is separated from centralized computation and decision-making, requiring the transfer of large amounts of data from periphery to central processors, at the cost of wiring, latency, fault tolerance and robustness. We envision a decentralized approach where intelligence is embedded in the sensing nodes, using a unique neuromorphic methodology to extract relevant information in robotic skins. Here we specifically address pain perception and the association of nociception with tactile perception to trigger the escape reflex in a sensorized robotic arm. The proposed system comprises self-healable materials and memtransistors as enabling technologies for the implementation of neuromorphic nociceptors, spiking local associative learning and communication. Configuring memtransistors as gated-threshold and -memristive switches, the demonstrated system features in-memory edge computing with minimal hardware circuitry and wiring, and enhanced fault tolerance and robustness.",

author = "John, {Rohit Abraham} and Naveen Tiwari and Patdillah, {Muhammad Iszaki Bin} and Kulkarni, {Mohit Rameshchandra} and Nidhi Tiwari and Joydeep Basu and Bose, {Sumon Kumar} and Ankit and Yu, {Chan Jun} and Amoolya Nirmal and Vishwanath, {Sujaya Kumar} and Chiara Bartolozzi and Arindam Basu and Nripan Mathews",

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doi = "10.1038/s41467-020-17870-6",

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AU - Tiwari, Nidhi

AU - Basu, Joydeep

AU - Bose, Sumon Kumar

AU - Ankit, null

AU - Yu, Chan Jun

AU - Nirmal, Amoolya

AU - Vishwanath, Sujaya Kumar

AU - Bartolozzi, Chiara

AU - Basu, Arindam

AU - Mathews, Nripan

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AB - Sensory information processing in robot skins currently rely on a centralized approach where signal transduction (on the body) is separated from centralized computation and decision-making, requiring the transfer of large amounts of data from periphery to central processors, at the cost of wiring, latency, fault tolerance and robustness. We envision a decentralized approach where intelligence is embedded in the sensing nodes, using a unique neuromorphic methodology to extract relevant information in robotic skins. Here we specifically address pain perception and the association of nociception with tactile perception to trigger the escape reflex in a sensorized robotic arm. The proposed system comprises self-healable materials and memtransistors as enabling technologies for the implementation of neuromorphic nociceptors, spiking local associative learning and communication. Configuring memtransistors as gated-threshold and -memristive switches, the demonstrated system features in-memory edge computing with minimal hardware circuitry and wiring, and enhanced fault tolerance and robustness.

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Self healable neuromorphic memtransistor elements for decentralized sensory signal processing in robotics

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