1 Citation
A single tunable filter can reduce the complexity, loss, and size when compared to switchable filter banks and enable new applications. Although magnetostatic wave tunable filters offer broad and continuous frequency tuning and high-quality factor (Q-factor), they consume high power and require large electromagnets to alter the magnetostatic wave velocity for filter frequency tuning. Here, we demonstrate miniature and high selectivity magnetostatic wave tunable filters with zero static power realized in Yttrium Iron Garnet thin films. The center frequency can be tuned via current pulses applied to a magnetic bias assembly from 3.36 GHz to 11.09 GHz with an insertion loss of 3.2 dB to 5.1 dB and out-of-band third order input intercept point (IIP3) of 41 to 44 dBm. Overall, the adaptability, wide frequency tuning range, and zero static power consumption of the tunable filter position it as a critical technology, effectively addressing challenges in broadband ADCs, RF transceivers, broadband digital phased array antennas, and interference mitigation in 5G and 6G networks. Broadly frequency tunable, high selectivity filters open new avenues for more efficient and dynamic RF front ends, ensuring optimal performance and seamless communication in the ever-evolving landscape of modern wireless technologies.