Seong-Yun Yun scite author profile

An artificial multisensory device applicable to insensor computing is demonstrated with a single-transistor neuron (1T-neuron) for multimodal perception. It simultaneously receives two sensing signals from visual and thermal stimuli. The 1T-neuron transforms these signals into electrical signals in the form of spiking and then fires them for a spiking neural network at the same time. This feature makes it feasible to realize input neurons for multimodal sensing. Visual and thermal sensing is achieved due to the inherent optical and thermal behaviors of the 1T-neuron. To demonstrate a neuromorphic multimodal sensing system with the artificial multisensory 1T-neuron, fingerprint recognition, widely used for biometric security, is implemented. Owing to the simultaneous sensing of heat as well as light, the proposed fingerprint recognition system composed of multisensory 1T-neurons not only identifies a genuine pattern but also judges whether or not it is forged.

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Wearable Bead-Based Triboelectric Nanogenerator with Dual-Mode Operation for Monitoring Abnormal Behavior in Dementia Patients

Son

Kim

Yun

et al. 2023

Preprint

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Thermally Stable Single-Transistor Neuron for Reliable Neuromorphic System

Chung

Han

Jae-Pil

et al. 2022

IEEE Electron Device Lett.

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Leaky FinFET for Reservoir Computing with Temporal Signal Processing

Han

Yun

et al. 2023

ACS Appl. Mater. Interfaces

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Reservoir computing can greatly reduce the hardware and training costs of recurrent neural networks with temporal data processing. To implement reservoir computing in a hardware form, physical reservoirs transforming sequential inputs into a high-dimensional feature space are necessary. In this work, a physical reservoir with a leaky fin-shaped field-effect transistor (L-FinFET) is demonstrated by the positive use of a short-term memory property arising from the absence of an energy barrier to suppress the tunneling current. Nevertheless, the L-FinFET reservoir does not lose its multiple memory states. The L-FinFET reservoir consumes very low power when encoding temporal inputs because the gate serves as an enabler of the write operation, even in the off-state, due to its physical insulation from the channel. In addition, the small footprint area arising from the scalability of the FinFET due to its multiple-gate structure is advantageous for reducing the chip size. After the experimental proof of 4-bit reservoir operations with 16 states for temporal signal processing, handwritten digits in the Modified National Institute of Standards and Technology dataset are classified by reservoir computing.

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Seong-Yun Yun

A flutter-driven triboelectric nanogenerator for harvesting energy of gentle breezes with a rear-fixed fluttering film

Artificial Multisensory Neuron with a Single Transistor for Multimodal Perception through Hybrid Visual and Thermal Sensing

Wearable Bead-Based Triboelectric Nanogenerator with Dual-Mode Operation for Monitoring Abnormal Behavior in Dementia Patients

Thermally Stable Single-Transistor Neuron for Reliable Neuromorphic System

Leaky FinFET for Reservoir Computing with Temporal Signal Processing

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