Presentation
3 October 2024 Liquid-crystal-based reconfigurable structural nonlinearity
Author Affiliations +
Abstract
Traditional neural networks (NNs) require substantial computing resources and energy. Photonics-based systems offer faster and more energy-efficient solutions. However, implementing nonlinear activation functions in photonics has been challenging due to the need for high-power optical sources and extended interaction lengths. The proposed solution uses structural nonlinearity, creating nonlinear output patterns with low energy use and simple digital NN training. The research develops a reconfigurable material platform using liquid crystal/polymer composite (LCPC) and metasurface to control scattering potentials dynamically. These results show that the LCPC’s phase distribution can be reliably controlled, enabling reconfiguration and repetition of scattering responses, which is crucial for advancing photonics-based neuromorphic computing.
Conference Presentation
© (2024) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Tsung-Hsien Lin, Zhiwen Liu, Xingjie Ni, and Iam-Choon Khoo "Liquid-crystal-based reconfigurable structural nonlinearity", Proc. SPIE PC13113, Photonic Computing: From Materials and Devices to Systems and Applications, PC131130O (3 October 2024); https://doi.org/10.1117/12.3026919
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KEYWORDS
Liquid crystals

Laser scattering

Spatial light modulators

Phase distribution

Photonic crystals

Reliability

Scattering

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