Dispersion-Oriented Inverse Design of Photonic-Crystal Fiber for Four-Wave Mixing Application

Dispersion-Oriented Inverse Design of Photonic-Crystal Fiber for Four-Wave Mixing Application

In this paper, we demonstrate the application of a deep learning neural network (DNN) in the dispersion-oriented inverse design of photonic-crystal fiber (PCF) for the fine-tuning of four-wave mixing (FWM). The empirical formula of PCF dispersion is applied instead of numerical simulation to generat...

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Veröffentlicht in:Photonics 2023-03, Vol.10 (3), p.294
Hauptverfasser: Gan, Linqiao, Yu, Fei, Wang, Yazhou, Wang, Ning, Zhu, Xinyue, Hu, Lili, Yu, Chunlei
Format: Artikel
Sprache:eng
Schlagworte:
Accuracy
Computer simulation
Crystal fibers
Deep learning
deep learning neural networks
Design
Finite element analysis
Four-wave mixing
Genetic algorithms
Imaging systems
Inverse design
Mathematical models
Medical imaging
Neural networks
Numerical analysis
Optimization
Phase matching
Photonic crystals
photonic-crystal fiber
Predictions
Semiconductors
Simulation methods
Spectrum analysis
Wave division multiplexing
Wavelength
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Zusammenfassung:In this paper, we demonstrate the application of a deep learning neural network (DNN) in the dispersion-oriented inverse design of photonic-crystal fiber (PCF) for the fine-tuning of four-wave mixing (FWM). The empirical formula of PCF dispersion is applied instead of numerical simulation to generate a large dataset of phase-matching curves of various PCF designs, which significantly improves the accuracy of the DNN prediction. The accuracies of DNNs’ predicted PCF structure parameters are all above 95%. The simulations of the DNN-predicted PCFs structure demonstrate that the FWM wavelength has an average numerical mean square error (MAE) of 1.92 nm from the design target. With the help of DNN, we designed and fabricated a specific PCF for wavelength conversion via FWM from 1064 nm to 770 nm for biomedical imaging applications. Pumped by a microchip laser at 1064 nm, the signal wavelength is measured at 770.2 nm.
ISSN:2304-6732
2304-6732
DOI:10.3390/photonics10030294