Highly reconfigurable silicon integrated microwave photonic filter towards next- generation wireless communication

Integrated microwave photonic filters (IMPFs) are capable of offering unparalleled performances in terms of superb spectral fineness, broadband, and more importantly, the reconfigurability, which encounter the trend of the next-generation wireless communication. However, to achieve high reconfigurability, previous works should adopt complicated system structures and modulation formats, which put great pressure on power con-sumption and controlment, and, therefore, impede the massive deployment of IMPF. Here, we propose a stream-lined architecture for a wideband and highly reconfigurable IMPF on the silicon photonics platform. For various practical filter responses, to avoid complex auxiliary devices and bias drift problems, a phase-modulated flexible sideband cancellation method is employed based on the intensity-consistent single-stage-adjustable cascaded-microring (ICSSA-CM). The IMPF exhibits an operation band extending to millimeter-wave (>= 30 GHz), and other extraordinary performances including high spectral resolution of 220 MHz and large rejection ratio of 60 dB are obtained. Moreover, Gb/s-level RF wireless communications are demonstrated for the first time towards real-world scenarios. The proposed IMPF provides broadband flexible spectrum control capabilities, showing great potential in the next-generation wireless communication. (c) 2023 Chinese Laser Press

Automated summary

This study proposes a wideband and highly reconfigurable integrated microwave photonic filter (IMPF) on the silicon photonics platform. By employing a phase-modulated flexible sideband cancellation method, the IMPF achieves various practical filter responses without complex auxiliary devices and bias drift problems. The IMPF exhibits exceptional performances including operation in the millimeter-wave band (>= 30 GHz), high spectral resolution (220 MHz), and large rejection ratio (60 dB), and it also demonstrates Gb/s-level RF wireless communications for real-world scenarios.