Photodetectors are devices that can convert incoming light into electrical signals, and they have become essential components in a wide range of applications, from digital cameras to LIDARS. These applications include optical communication, imaging, remote sensing, environmental monitoring, and more.

The characteristics of the incident light can vary depending on the application, including the excitation wavelength, intensity, and mode (continuous or pulsed). Moreover, different applications may have different requirements. For example, in optical communication, accuracy is of utmost importance, whereas for remote sensing, phase noise may be a critical metric. To optimize the performance of photodetectors for a particular application, one must consider several factors and balance the tradeoffs among multiple performance metrics.

In addition to numerical optimization, we employ machine learning algorithms in our research for both forward and inverse problems. Regarding the former, we pay particular attention to developing energy-efficient neural networks designed in accordance with the working principles of the devices we are studying.

We are currently investigating two distinct inverse problems: electromagnetic inversion using neural networks and inverse device design. In electromagnetic inversion, we collect scattering data from receiver antennas positioned around a black box and attempt to deduce the contents of the box. Through recent research, we have discovered that using a limited number of antennas with broadband signals is more effective than using a large number of antennas operating at a single frequency. The second problem that we are exploring involves designing photonic devices through the use of machine learning algorithms. Our goal is to determine whether it is possible to design superior devices solely through analysis of data.