Fully integrated hybrid multimode-multiwavelength photonic processor with picosecond latency (2411.15339v1)

Abstract: High-speed signal processing is essential for maximizing data throughput in emerging communication applications, like multiple-input multiple-output (MIMO) systems and radio-frequency (RF) interference cancellation. However, as these technologies scale, they increase hardware complexity, computing power demands, and create significant digital signal processing (DSP) challenges. While transistor miniaturization has improved digital electronic processors, they still face physical bottlenecks, limiting computational throughput and increasing DSP latency. Photonic processors present a promising alternative, offering large bandwidth, low loss, parallel processing, and low latency. Yet, scalability in photonic processors remains limited by system integration, device size, and on-chip multiplexing challenges. Here, we introduce a scalable on-chip hybrid multiplexed photonic processor, combining mode-division multiplexing (MDM) and wavelength-division multiplexing (WDM). This marks the first implementation of a monolithically integrated MDM-WDM-compatible processor, featuring mode multiplexers, multimode microring resonators, and multimode balanced photodetectors. Furthermore, we demonstrate real-time unscrambling of 5 Gb/s non-return-to-zero optical MIMO signals and RF phase-shift keying signal unjamming. Our system's 30 ps processing latency makes it ideal for real-time MIMO and RF applications. Our analysis reveals that hybrid MDM-WDM multiplexing improves the number of operations per second by 4.1 times over spatially multiplexed WDM configurations, positioning it as a strong candidate for next-generation large-scale photonic processors.