Abstract

Multipurpose programmable photonic processors have recently emerged as a solution to provide cost-effective and general-purpose functionality for a myriad of photonic applications. Inspired by programmable electronics, the design of these devices lies on generic photonic integrated hardware based on two-dimensional waveguide meshes comprised of tunable couplers and phase actuators. Extending these meshes allows the implementation of more complex structures and functionalities. However, there are design trade-offs arising from parasitic effects coming from fabrication and their dynamic operation. Since the time spent during the design cycle and validation of these complex systems usually involves a costly, risky and time-consuming processes, this work proposes and compares two simulation tools to predict the spectral response of any 2D integrated photonic mesh circuit composed of an arbitrary number of coupled cells. These methods reduce development costs, speed up the growth of new circuit designs, and are a fundamental tool for the development of programmable photonic libraries.

Principles, fundamentals, and applications of programmable integrated photonics

Daniel Pérez, Ivana Gasulla, Prometheus Das Mahapatra, and José Capmany
Adv. Opt. Photon. 12(3) 709-786 (2020)

Effects of coupling and phase imperfections in programmable photonic hexagonal waveguide meshes

Iman Zand and Wim Bogaerts
Photon. Res. 8(2) 211-218 (2020)

Scalable analysis for arbitrary photonic integrated waveguide meshes

Daniel Pérez and Jose Capmany
Optica 6(1) 19-27 (2019)

Auto-routing algorithm for field-programmable photonic gate arrays

Aitor López, Daniel Pérez, Prometheus DasMahapatra, and José Capmany
Opt. Express 28(1) 737-752 (2020)

Silicon nitride programmable photonic processor with folded heaters

Daniel Pérez-López, Ana Gutiérrez, and José Capmany
Opt. Express 29(6) 9043-9059 (2021)