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Autores principales: Zhang, Ziyao, Wang, Yizhi, Yao, Chunhui, Huang, Huiyu, Ma, Rui, Du, Xin, Zhang, Wanlu, Shi, Zhitian, Chen, Minjia, Yan, Ting, Ming, Liang, Ye, Yuxiao, Penty, Richard, Cheng, Qixiang
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2506.23187
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author Zhang, Ziyao
Wang, Yizhi
Yao, Chunhui
Huang, Huiyu
Ma, Rui
Du, Xin
Zhang, Wanlu
Shi, Zhitian
Chen, Minjia
Yan, Ting
Ming, Liang
Ye, Yuxiao
Penty, Richard
Cheng, Qixiang
author_facet Zhang, Ziyao
Wang, Yizhi
Yao, Chunhui
Huang, Huiyu
Ma, Rui
Du, Xin
Zhang, Wanlu
Shi, Zhitian
Chen, Minjia
Yan, Ting
Ming, Liang
Ye, Yuxiao
Penty, Richard
Cheng, Qixiang
contents Measurements of microscale surface patterns are essential for process and quality control in industries across semiconductors, micro-machining, and biomedicines. However, the development of miniaturized and intelligent profiling systems remains a longstanding challenge, primarily due to the complexity and bulkiness of existing benchtop systems required to scan large-area samples. A real-time, in-situ, and fast detection alternative is therefore highly desirable for predicting surface topography on the fly. In this paper, we present an ultracompact geometric profiler based on photonic integrated circuits, which directly encodes the optical reflectance of the sample and decodes it with a neural network. This platform is free of complex interferometric configurations and avoids time-consuming nonlinear fitting algorithms. We show that a silicon programmable circuit can generate pseudo-random kernels to project input data into higher dimensions, enabling efficient feature extraction via a lightweight one-dimensional convolutional neural network. Our device is capable of high-fidelity, fast-scanning-rate thickness identification for both smoothly varying samples and intricate 3D printed emblem structures, paving the way for a new class of compact geometric sensors.
format Preprint
id arxiv_https___arxiv_org_abs_2506_23187
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle 3D surface profiling via photonic integrated geometric sensor
Zhang, Ziyao
Wang, Yizhi
Yao, Chunhui
Huang, Huiyu
Ma, Rui
Du, Xin
Zhang, Wanlu
Shi, Zhitian
Chen, Minjia
Yan, Ting
Ming, Liang
Ye, Yuxiao
Penty, Richard
Cheng, Qixiang
Optics
Measurements of microscale surface patterns are essential for process and quality control in industries across semiconductors, micro-machining, and biomedicines. However, the development of miniaturized and intelligent profiling systems remains a longstanding challenge, primarily due to the complexity and bulkiness of existing benchtop systems required to scan large-area samples. A real-time, in-situ, and fast detection alternative is therefore highly desirable for predicting surface topography on the fly. In this paper, we present an ultracompact geometric profiler based on photonic integrated circuits, which directly encodes the optical reflectance of the sample and decodes it with a neural network. This platform is free of complex interferometric configurations and avoids time-consuming nonlinear fitting algorithms. We show that a silicon programmable circuit can generate pseudo-random kernels to project input data into higher dimensions, enabling efficient feature extraction via a lightweight one-dimensional convolutional neural network. Our device is capable of high-fidelity, fast-scanning-rate thickness identification for both smoothly varying samples and intricate 3D printed emblem structures, paving the way for a new class of compact geometric sensors.
title 3D surface profiling via photonic integrated geometric sensor
topic Optics
url https://arxiv.org/abs/2506.23187