学习迁移
计算机科学
卷积神经网络
匹配(统计)
深度学习
趋同(经济学)
人工智能
数据传输
机器学习
人工神经网络
数据建模
数学
经济增长
统计
计算机网络
数据库
经济
作者
Rohit Unni,Kan Yao,Yuebing Zheng
出处
期刊:Advanced photonics
[SPIE - International Society for Optical Engineering]
日期:2024-10-08
卷期号:6 (05)
被引量:17
标识
DOI:10.1117/1.ap.6.5.056006
摘要
Machine learning techniques have gained popularity in nanophotonics research, being applied to predict optical properties, and inversely design structures. However, one limitation is the cost of acquiring training data, as complex structures require time-consuming simulations. To address this, researchers have explored using transfer learning, where pre-trained networks can facilitate convergence with fewer data for related tasks, but application to more difficult tasks is still limited. In this work, a nested transfer learning approach is proposed, training models to predict structures of increasing complexity, with transfer between each model and few data used at each step. This allows modeling thin film stacks with higher optical complexity than previously reported. For the forward model, a bidirectional recurrent neural network is utilized, which excels in modeling sequential inputs. For the inverse model, a convolutional mixture density network is employed. In both cases, a relaxed choice of materials at each layer is introduced, making the approach more versatile. The final nested transfer models display high accuracy in retrieving complex arbitrary spectra and matching idealized spectra for specific applications-focused cases such as selective thermal emitters, while keeping data requirements modest. Our nested transfer learning approach represents a promising avenue for addressing data acquisition challenges.
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