Hydrogel-Gated FETs in Neuromorphic Computing to Mimic Biological Signal: A Review

Bag, Sankar Prasad; Lee, Suyoung; Song, Jaeyoon; Kim, Jinsink

doi:10.3390/bios14030150

Biosensors

2024

DOI: 10.3390/bios14030150

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Hydrogel-Gated FETs in Neuromorphic Computing to Mimic Biological Signal: A Review

Sankar Prasad Bag,

Suyoung Lee,

Jaeyoon Song

et al.

Abstract: Hydrogel-gated synaptic transistors offer unique advantages, including biocompatibility, tunable electrical properties, being biodegradable, and having an ability to mimic biological synaptic plasticity. For processing massive data with ultralow power consumption due to high parallelism and human brain-like processing abilities, synaptic transistors have been widely considered for replacing von Neumann architecture-based traditional computers due to the parting of memory and control units. The crucial componen… Show more

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Enhancing Assistive Technologies With Neuromorphic Computing

Anil Chandra,

Ananthakumar,

Raghavan

2024

Advances in Computational Intelligence and Robotics

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The development of intelligent neuroprosthetics, which promise to augment human brain function is vital for augmentative assistive technologies. Neuromorphic sensors and processors are particularly adept at mimicking the brain's efficient sensory processing, offering assistive devices an advanced capability to perceive and interpret complex environmental stimuli. The application of these technologies in brain computer interfaces suggests a future where transformative advancements are not only possible but imminent, facilitating novel methods of human-computer interaction and providing insights into the intricate workings of the brain through advanced AI and machine learning techniques. This paper explores the integration of neuromorphic technologies with brain-computer interfaces (BCIs), highlighting the potential to enhance assistive devices and revolutionize communication and healthcare. However, the realization of neuromorphic computing's full potential within BCIs is contingent upon overcoming significant technological and ethical challenges.

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Enhancing Assistive Technologies With Neuromorphic Computing

Anil Chandra,

Ananthakumar,

Raghavan

2024

Advances in Computational Intelligence and Robotics

View full text Add to dashboard Cite

show abstract

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Hydrogel-Gated FETs in Neuromorphic Computing to Mimic Biological Signal: A Review

Cited by 1 publication

References 113 publications

Enhancing Assistive Technologies With Neuromorphic Computing

Enhancing Assistive Technologies With Neuromorphic Computing

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