Integrated RF-photonic Filters via Photonic-Phononic Emit-Receive Operations

TL;DR

This paper introduces a novel integrated silicon-based RF-photonic filter that combines microwave photonic filtering with high-Q phononic processing, achieving MHz-bandwidth filtering with low RF insertion loss and high efficiency.

Contribution

It presents a new integrated photonic-phononic emit-receive filter that enables MHz-bandwidth filtering with low loss and high efficiency, advancing RF signal processing technology.

Findings

Achieved MHz-bandwidth band-pass filtering with low RF insertion loss.

Demonstrated record-high internal efficiency for emit-receive operations.

Showed suitability for creating serial filter banks with minimal fidelity loss.

Abstract

The creation of high-performance narrowband filters is of great interest for many RF-signal processing applications. To this end, numerous schemes for electronic, MEMS-based, and microwave photonic filters have been demonstrated. Filtering schemes based on microwave photonic systems offer superior flexibility and tunability to traditional RF filters. However, these optical-based filters are typically limited to GHz-widths and often have large RF insertion losses, posing challenges for integration into high-fidelity radiofrequency circuits. In this article, we demonstrate a novel type of microwave filter that combines the attractive features of microwave photonic filters with high-Q phononic signal processing using a photonic-phononic emit-receive process. Through this process, a RF signal encoded on a guided optical wave is transduced onto a GHz-frequency acoustic wave, where it may be filtered through shaping of acoustic transfer functions before being re-encoded onto a spatially separate optical probe. This emit-receive functionality, realized in an integrated silicon waveguide, produces MHz-bandwidth band-pass filtering while supporting low RF insertion losses necessary for high dynamic range in a microwave photonic link. We also demonstrate record-high internal efficiency for emit-receive operations of this type, and show that the emit-receive operation is uniquely suitable for the creation of serial filter banks with minimal loss of fidelity. This photonic-phononic emitter-receiver represents a new method for low-distortion signal-processing in an integrated all-silicon device.