Energy-efficient programmable integrated photonics via optimized Euler rotations
摘要
Programmable integrated photonics (PIP) has emerged as a powerful on-chip platform for optical signal processing and computing, enabling the implementation of reconfigurable NN unitary matrix transformations through meshes of tunable interferometers, which realize 22 unitary matrices. However, the energy consumption associated with phase-shifter actuation is becoming a major limitation to the scalability of PIP platforms. Here, we introduce a geometric framework for energy optimization in PIP circuits by exploiting the representation of 22 unitary matrices as concatenations of basic Euler rotations on the Bloch sphere. We show that equivalent implementations of the same NN unitary matrix (N 2) can exhibit markedly different energy costs depending on the rotation trajectories on the Bloch sphere implemented by each interferometer. Leveraging this insight, we identify minimum-energy configurations by systematically selecting the shortest rotation trajectories. We experimentally and numerically validate the proposed approach in diverse silicon PIP architectures, including feedforward and multipurpose hexagonal meshes, neural network accelerators, and photonic quantum-gate implementations. These results establish a general route toward more energy-efficient large-scale PIP processors for classical and quantum signal processing and computing applications.
引用
@article{arxiv.2605.19570,
title = {Energy-efficient programmable integrated photonics via optimized Euler rotations},
author = {Pablo Martínez-Carrasco Romero and Andrés Macho-Ortíz and José Roberto Rausell-Campo and Francisco Javier Fraile-Peláez and José Capmany Francoy},
journal= {arXiv preprint arXiv:2605.19570},
year = {2026}
}