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Main Authors: Jia, Hao, Yang, Shanglin, He, Jiajun, Liu, Shuo, Chen, Haoxiang, Shang, Ce, Ma, Shaojie, Han, Peng, Lee, Ching Hua, Gao, Zhen, Lai, Yun, Cui, Tie Jun
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.24463
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author Jia, Hao
Yang, Shanglin
He, Jiajun
Liu, Shuo
Chen, Haoxiang
Shang, Ce
Ma, Shaojie
Han, Peng
Lee, Ching Hua
Gao, Zhen
Lai, Yun
Cui, Tie Jun
author_facet Jia, Hao
Yang, Shanglin
He, Jiajun
Liu, Shuo
Chen, Haoxiang
Shang, Ce
Ma, Shaojie
Han, Peng
Lee, Ching Hua
Gao, Zhen
Lai, Yun
Cui, Tie Jun
contents Topolectrical circuits provide a versatile platform for exploring and simulating modern physical models. However, existing approaches suffer from incomplete programmability and ineffective feature prediction and control mechanisms, hindering the investigation of physical phenomena on an integrated platform and limiting their translation into practical applications. Here, we present a deep learning empowered programmable topolectrical circuits (DLPTCs) platform for physical modeling and analysis. By integrating fully independent, continuous tuning of both on site and off site terms of the lattice Hamiltonian, physics graph informed inverse state design, and immediate hardware verification, our system bridges the gap between theoretical modeling and practical realization. Through flexible control and adiabatic path engineering, we experimentally observe the boundary states without global symmetry in higher order topological systems, their adiabatic phase transitions, and the flat band like characteristic corresponding to Landau levels in the circuit. Incorporating a physics graph informed mechanism with a generative AI model for physics exploration, we realize arbitrary, position controllable on board Anderson localization, surpassing conventional random localization. Utilizing this unique capability with high fidelity hardware implementation, we further demonstrate a compelling cryptographic application: hash based probabilistic information encryption by leveraging Anderson localization with extensive disorder configurations, enabling secure delivery of full ASCII messages.
format Preprint
id arxiv_https___arxiv_org_abs_2510_24463
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Deep-Learning-Empowered Programmable Topolectrical Circuits
Jia, Hao
Yang, Shanglin
He, Jiajun
Liu, Shuo
Chen, Haoxiang
Shang, Ce
Ma, Shaojie
Han, Peng
Lee, Ching Hua
Gao, Zhen
Lai, Yun
Cui, Tie Jun
Disordered Systems and Neural Networks
Materials Science
Computational Physics
Topolectrical circuits provide a versatile platform for exploring and simulating modern physical models. However, existing approaches suffer from incomplete programmability and ineffective feature prediction and control mechanisms, hindering the investigation of physical phenomena on an integrated platform and limiting their translation into practical applications. Here, we present a deep learning empowered programmable topolectrical circuits (DLPTCs) platform for physical modeling and analysis. By integrating fully independent, continuous tuning of both on site and off site terms of the lattice Hamiltonian, physics graph informed inverse state design, and immediate hardware verification, our system bridges the gap between theoretical modeling and practical realization. Through flexible control and adiabatic path engineering, we experimentally observe the boundary states without global symmetry in higher order topological systems, their adiabatic phase transitions, and the flat band like characteristic corresponding to Landau levels in the circuit. Incorporating a physics graph informed mechanism with a generative AI model for physics exploration, we realize arbitrary, position controllable on board Anderson localization, surpassing conventional random localization. Utilizing this unique capability with high fidelity hardware implementation, we further demonstrate a compelling cryptographic application: hash based probabilistic information encryption by leveraging Anderson localization with extensive disorder configurations, enabling secure delivery of full ASCII messages.
title Deep-Learning-Empowered Programmable Topolectrical Circuits
topic Disordered Systems and Neural Networks
Materials Science
Computational Physics
url https://arxiv.org/abs/2510.24463