A Digital Optical Switch Based on a Thermally Tuned Multimode Waveguide Grating Filter
Abstract
All-optical switching technology is a key solution to the future energy crisis in AI computing, where the performance of optical switches plays a critical role. Conventional integrated optical switches typically suffer from poor robustness to voltage fluctuations, fabrication variations, and temperature drifts. These limitations necessitate complex high-precision real-time calibration and control circuits, which greatly restrict their practical use. This paper presents a digital optical switch based on a thermally tuned multimode waveguide grating (MWG) filter. The switch maintains its on- and off-states across two voltage ranges: 0-0.7 V and 1.1-1.7 V, with a wide operating voltage margin of 0.6 V. It also exhibits excellent robustness to fabrication variations and temperature drifts. By introducing an innovative combination of positive dispersion and parabolic apodization design, the power consumption is reduced by two-thirds, reaching a maximum of only 6 mW. Owing to its low power consumption and wide voltage range, the device can be directly driven by digital signals, allowing for a simplified driver circuitry and a significant reduction in both energy use and overall cost. In addition, the switch offers low insertion loss (<0.5 dB), high extinction ratio (>20 dB), and fast switching (300 {\mu}s), demonstrating excellent overall performance and promising application prospects.
Cite
@article{arxiv.2604.17263,
title = {A Digital Optical Switch Based on a Thermally Tuned Multimode Waveguide Grating Filter},
author = {Hongyu Wang and Xudong Gao and Chuanneng Luo and Haijiang Yu and Mengxue Tao and Hanlin Qin},
journal= {arXiv preprint arXiv:2604.17263},
year = {2026}
}
Comments
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