We are interested in exploring the limit in using deep learning (DL) to study the electromagnetic (EM) response for complex and random metasurfaces, without any specific applications in mind. For simplicity, we focus on a simple pure reflection problem of a broadband EM plane wave incident normally on such complex metasurfaces in the frequency regime of 2–12 GHz. In doing so, we create a DL-based framework called the metasurface design deep convolutional neural network (MSDCNN) for both forward and inverse designs of three different classes of complex metasurfaces: (a) arbitrary connecting polygons, (b) basic pattern combination, and (c) fully random binary patterns. The performance of each metasurface is evaluated and cross-benchmarked. De...
The advent of metasurfaces in recent years has ushered in a revolutionary means to manipulate the be...
In this paper, a Machine Learning (ML), and more specifically, a Deep Learning (DL) approach, is app...
Complex nanophotonic structures hold the potential to deliver exquisitely tailored optical responses...
A deep learning neural network model in conjunction with a method to incorporate auxiliary surface w...
Supporting dataElectromagnetic environments are becoming increasingly complex and congested, creatin...
Metasurfaces are composed of a two-dimensional array of carefully engineered subwavelength structure...
Metamaterials, which are not found in nature, are used to increase the performance of antennas with ...
The demonstration of exotic electromagnetic metasurfaces has benefited from the advance of computati...
Electromagnetic environments are becoming increasingly complex and congested, creating a growing cha...
A convolutional neural network (CNN) based deep learning (DL) technique for electromagnetic imaging ...
Metasurface has demonstrated potential and novel optical properties in previous research. The prevai...
In this paper, a convolutional neural network (CNN)-based deep learning (DL) architecture for the so...
Metasurfaces are subwavelength-structured artificial media that can shape and localize electromagnet...
As the current standardization for the 5G networks nears completion, work towards understanding the ...
International audienceIn this chapter, we analyzed some applications of deep learning methods to ele...
The advent of metasurfaces in recent years has ushered in a revolutionary means to manipulate the be...
In this paper, a Machine Learning (ML), and more specifically, a Deep Learning (DL) approach, is app...
Complex nanophotonic structures hold the potential to deliver exquisitely tailored optical responses...
A deep learning neural network model in conjunction with a method to incorporate auxiliary surface w...
Supporting dataElectromagnetic environments are becoming increasingly complex and congested, creatin...
Metasurfaces are composed of a two-dimensional array of carefully engineered subwavelength structure...
Metamaterials, which are not found in nature, are used to increase the performance of antennas with ...
The demonstration of exotic electromagnetic metasurfaces has benefited from the advance of computati...
Electromagnetic environments are becoming increasingly complex and congested, creating a growing cha...
A convolutional neural network (CNN) based deep learning (DL) technique for electromagnetic imaging ...
Metasurface has demonstrated potential and novel optical properties in previous research. The prevai...
In this paper, a convolutional neural network (CNN)-based deep learning (DL) architecture for the so...
Metasurfaces are subwavelength-structured artificial media that can shape and localize electromagnet...
As the current standardization for the 5G networks nears completion, work towards understanding the ...
International audienceIn this chapter, we analyzed some applications of deep learning methods to ele...
The advent of metasurfaces in recent years has ushered in a revolutionary means to manipulate the be...
In this paper, a Machine Learning (ML), and more specifically, a Deep Learning (DL) approach, is app...
Complex nanophotonic structures hold the potential to deliver exquisitely tailored optical responses...