Abstract
Topological states in photonics offer novel prospects for guiding and manipulating photons and facilitate the development of modern optical components for a variety of applications. Over the past few years, photonic topology physics has evolved and unveiled various unconventional optical properties in these topological materials, such as silicon photonic crystals. However, the design of such topological states still poses a significant challenge. Conventional optimization schemes often fail to capture their complex high dimensional design space. In this manuscript, we develop a deep learning framework to map the design space of topological states in the photonic crystals. This framework overcomes the limitations of existing deep learning implementations. Specifically, it reconciles the dimension mismatch between the input (topological properties) and output (design parameters) vector spaces and the non-uniqueness that arises from one-to-many function mappings. We use a fully connected deep neural network (DNN) architecture for the forward model and a cyclic convolutional neural network (cCNN) for the inverse model. The inverse architecture contains the pre-trained forward model in tandem, thereby reducing the prediction error significantly.
Highlights
With the advent of topological phases of matter in electronic materials, the exploration of band properties in photonic materials have received a huge impetus
The different layers of neurons in the network enable learning of complex mathematical functions and enable the development of forward and inverse models in estimating the properties of topological photonic crystals (PhCs) devices
Based on the symmetry in our crystal structure, we choose an architecture of the neural network that is compatible with the symmetry of targeted physics behind the model
Summary
With the advent of topological phases of matter in electronic materials, the exploration of band properties in photonic materials have received a huge impetus. The different layers of neurons in the network enable learning of complex mathematical functions and enable the development of forward and inverse models in estimating the properties of topological PhC devices. Current challenges of the DNN implementations are (1) Dimensional mismatch between input and output space (2) Inverse problem estimation due to implicit conflicting instances of one-to-many mapping functions. In this manuscript, we explore machine learning-based methods to design photonic crystal structures with targeted topological properties. We thereby attempt to solve the presented challenges i.e., dimensional mismatch in mapping the topological PhC design space and inverse problem estimation. The presented formalism can be scaled to more complex structures in 2D and 3D geometries
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