A Radio Frequency Non-reciprocal Network Based on Switched Acoustic Delay Lines

TL;DR

This paper presents the first non-reciprocal RF network using switched acoustic delay lines, achieving high contrast and low loss, with potential for wide-band, programmable chip-scale systems.

Contribution

It introduces a novel non-reciprocal network based on switched low-loss acoustic delay lines with detailed theoretical and experimental validation.

Findings

Achieved 18.8 dB non-reciprocal contrast at 155 MHz

Realized a record low switching frequency of 877.19 kHz

Demonstrated 6.6 dB insertion loss and 25.4 dB isolation

Abstract

This work demonstrates the first non-reciprocal network based on switched low-loss acoustic delay lines. The 4-port circulator is built upon a recently reported frequency-independent, programmable, non-reciprocal framework based on switched delay lines. The design space for such a system, including the origins of the insertion loss and harmonic responses, is theoretically investigated, illustrating that the key to better performance and low-cost modulation signal synthesis lies in a large delay. To implement a large delay, we resort to in-house fabricated low-loss, wide-band lithium niobate (LiNbO3) SH0 mode acoustic delay lines employing single-phase unidirectional transducers (SPUDT). The 4-port circulator, consisting of two switch modules and one delay line module, has been modularly designed, assembled, and tested. The design process employs time-domain full circuit simulation and the results match well with measurements. A 18.8 dB non-reciprocal contrast between insertion loss (IL = 6.6 dB) and isolation (25.4 dB) has been achieved over a fractional bandwidth of 8.8% at a center frequency 155 MHz, using a record low switching frequency of 877.19 kHz. The circulator also shows 25.9 dB suppression for the intra-modulated tone and 30 dBm for IIP3. Upon further development, such a system can potentially lead to future wide-band, low-loss chip-scale nonreciprocal RF systems with unprecedented programmability.