Abstract
When designing new optical devices, many simulations must be conducted to determine the optimal design parameters. Therefore, fast and accurate simulations are essential for designing optical devices. In this work, we introduce a deep learning approach that accelerates a simulator solving frequency-domain Maxwell equations. Our model achieves high accuracy while predicting transmittance per wavelength in 2D slit arrays under certain conditions to achieve 160,000 times faster results than the simulator. We generated a dataset using an open-source simulator and compared its performance with those of other machine learning models. Additionally, we propose a new loss function and performance evaluation method for creating better performance models with multiple regression outputs from one input source. We observed that using a loss function that adds binary cross-entropy loss, which predicts whether the differential of the transmittance is positive or negative at wavelengths adjacent to the root mean-squared error of the transmittance value, is more effective for predicting variations in multiple regression outputs. The simulation results show that a four-layer convolutional neural network model demonstrates the best accuracy (R2 score: 0.86). The overall approach presented here is expected to be useful for simulating and designing optical devices.
Highlights
When designing new optical devices, many simulations must be conducted to determine the optimal design parameters
CNNs constitute the major architecture behind the popular object detection models, including regionbased convolutional neural networks (R-CNN)[3], fast R-CNN4, and faster R-CNN5
An emerging application of CNN is physics-informed deep learning[17], which is a technique for solving supervised learning tasks while respecting a given law of physics described by its general nonlinear partial differential equations
Summary
When designing new optical devices, many simulations must be conducted to determine the optimal design parameters. Over the past few years, convolutional neural networks (CNNs) have revolutionised the way we solve image classification problems[1, 2] Owing to their advantages, such as feature learning and high computational efficiency, CNNs are used in various computer vision tasks. CNNs constitute the major architecture behind the popular object detection models, including regionbased convolutional neural networks (R-CNN)[3], fast R-CNN4, and faster R-CNN5 They are used in object tracking[6], object r ecognition[7], and semantic s egmentation[8] to improve the performance of the computer vision approaches. Many researchers have attempted to solve the problem of accurately and quickly estimating partial differential equations that take considerable time to solve, such as Burgers’ equation, Navier–Stokes e quation[20], and Maxwell’s equations[21]
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