We demonstrate the use of machine learning through convolutional neural networks to solve inverse design problems of optical resonator engineering. The neural network finds a harmonic modulation of a spherical mirror to generate a resonator mode with a given target topology (“mode on-demand”). The procedure allows us to optimize the shape of mirrors to achieve a significantly enhanced coupling strength and cooperativity between a resonator photon and a quantum emitter located at the center of the resonator. In a second example, a double-peak mode is designed which would enhance the interaction between two quantum emitters, e.g., for quantum information processing
For many applications in quantum technology or optical sensing strong coupling between light and mic...
In the past decade, machine learning techniques, in particular artificial neural networks (ANNs), h...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
We demonstrate the use of machine learning through convolutional neural networks to solve inverse de...
Machine learning offers the potential to revolutionize the inverse design of complex nanophotonic co...
We present our work on using deep neural networks for the prediction of the optical properties of na...
Reaching the true potential of nanophotonic devices requires the broadband control of spectral and a...
Computational inverse-design and forward perdition approaches provide promising approaches for on-de...
Distributed Bragg Reflectors are optical structures capable of manipulating light behaviour, which a...
Deep learning has become the dominant approach in artificial intelligence to solve complex data-driv...
We report an approach assisted by deep learning to design spectrally sensitive multiband absorbers t...
Inverse design of a metasurface involves searching parameters in a high‐dimensional space, which nee...
In this Letter, we demonstrate how harmonic oscillator equations can be integrated in a neural netwo...
We show that the free-form inverse design of nanophotonic matasurfaces can be solved with a modified...
Data-driven models have been increasingly used in recent years. However, their application to explor...
For many applications in quantum technology or optical sensing strong coupling between light and mic...
In the past decade, machine learning techniques, in particular artificial neural networks (ANNs), h...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
We demonstrate the use of machine learning through convolutional neural networks to solve inverse de...
Machine learning offers the potential to revolutionize the inverse design of complex nanophotonic co...
We present our work on using deep neural networks for the prediction of the optical properties of na...
Reaching the true potential of nanophotonic devices requires the broadband control of spectral and a...
Computational inverse-design and forward perdition approaches provide promising approaches for on-de...
Distributed Bragg Reflectors are optical structures capable of manipulating light behaviour, which a...
Deep learning has become the dominant approach in artificial intelligence to solve complex data-driv...
We report an approach assisted by deep learning to design spectrally sensitive multiband absorbers t...
Inverse design of a metasurface involves searching parameters in a high‐dimensional space, which nee...
In this Letter, we demonstrate how harmonic oscillator equations can be integrated in a neural netwo...
We show that the free-form inverse design of nanophotonic matasurfaces can be solved with a modified...
Data-driven models have been increasingly used in recent years. However, their application to explor...
For many applications in quantum technology or optical sensing strong coupling between light and mic...
In the past decade, machine learning techniques, in particular artificial neural networks (ANNs), h...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....