Your search keyword '"Chien, Yu-Chieh"' showing total 3 results

1. Switching Dynamics in Anti‐Ferroelectric Transistor for Multimodal Reservoir Computing.

Author

Shi, Yufei, Duong, Ngoc Thanh, Chien, Yu‐Chieh, Li, Sifan, Xiang, Heng, Zheng, Haofei, and Ang, Kah‐Wee

Subjects

ANTIFERROELECTRIC materials, RECURRENT neural networks, STANDARD deviations, TIME series analysis, ZIRCONIUM oxide

Abstract

Spatial‐temporal time series analysis and forecasting are crucial for understanding dynamic systems and making informed decisions. Recurrent neural networks (RNNs) have paved the way for reservoir computing (RC), a method enabling effective temporal information processing at low training costs. While software‐based RC performs well, physical RC systems face challenges like slow processing speed and limited state richness, leading to high hardware costs. This study introduces an innovative approach, i.e., the antiferroelectric field effect transistor‐based RC (AFeFET‐based RC) system for efficient temporal data processing. By exploiting the fading memory property inherent in hafnium oxide‐based antiferroelectric material, this system demonstrates promise for physical RC implementation. Moreover, it leverages the light sensitivity of 2D molybdenum disulfide (MoS2) channels for controllable temporal dynamics under electrical and optical stimuli. This dual‐mode modulation significantly enriches the reservoir state, boosting overall system performance. Experimental tests on standard benchmarking tasks using the AFeFET‐based RC system yielded impressive accuracy results (95.4%) in spoken‐digit recognition and a remarkable normalized root mean square error (NRMSE) of 0.015 in Mackey–Glass time series prediction. [ABSTRACT FROM AUTHOR]

Published

2024

2. A Dynamic Memory for Reservoir Computing Utilizing Ion Migration in CuInP2S6.

Author

Wu, Yangwu, Duong, Ngoc Thanh, Chien, Yu‐Chieh, Liu, Song, and Ang, Kah‐Wee

Subjects

ION migration & velocity, KELVIN probe force microscopy, STANDARD deviations, RECURRENT neural networks, ELECTRIC stimulation, TIME series analysis

Abstract

Time‐series analysis and forecasting play a vital role in the fields of economics and engineering. Neuromorphic computing, particularly recurrent neural networks (RNNs), has emerged as an effective approach to address these tasks. Reservoir computing (RC), a type of RNN, offers a powerful and efficient solution for handling nonlinear information in high‐dimensional spaces and addressing temporal tasks. CuInP2S6 (CIPS), a van der Waals material with ion conductivity, shows promise for sequential task processing. Here, a synapse device based on CIPS is demonstrated that exhibits temporal dynamics under electrical stimulation. By controlling Cu+ ion migration, this study successfully emulates synaptic performance, including potentiation and depression characteristics, and RC. Migration of Cu+ ions is confirmed using piezoresponse and Kelvin probe force microscopy. The device achieves low normalized root mean square errors (NRMSE) of 0.04762 and 0.01402 for the Hénon map and Mackey‐Glass series tasks, respectively. For real‐life time‐series prediction based on the Jena temperature database, an overall NRMSE of 0.03339 is achieved. These results highlight the potential of CIPS ion conductivity for real‐time signal processing in machine learning, expanding applications in neuromorphic computing. [ABSTRACT FROM AUTHOR]

Published

2024

3. Enhancing Memory Window Efficiency of Ferroelectric Transistor for Neuromorphic Computing via Two‐Dimensional Materials Integration.

Author

Xiang, Heng, Chien, Yu‐Chieh, Li, Lingqi, Zheng, Haofei, Li, Sifan, Duong, Ngoc Thanh, Shi, Yufei, and Ang, Kah‐Wee

Subjects

*FIELD-effect transistors, *NONVOLATILE memory, *ONLINE education, *ZIRCONIUM oxide, *SYNAPSES

Abstract

In‐memory computing, particularly neuromorphic computing, has emerged as a promising solution to overcome the energy and time‐consuming challenges associated with the von Neumann architecture. The ferroelectric field‐effect transistor (FeFET) technology, with its fast and energy‐efficient switching and nonvolatile memory, is a potential candidate for enabling both computing and memory within a single transistor. In this study, the capabilities of an integrated ferroelectric HfO2 and 2D MoS2 channel FeFET in achieving high‐performance 4‐bit per cell memory with low variation and power consumption synapses, while retaining the ability to implement diverse learning rules, are demonstrated. Notably, this device accurately recognizes MNIST handwritten digits with over 94% accuracy using online training mode. These results highlight the potential of FeFET‐based in‐memory computing for future neuromorphic computing applications. [ABSTRACT FROM AUTHOR]

Published

2023