Digitally Tunable Acoustic Resonator for 5G Communication Systems

Increases Signal Processing Configurability and Tunability to Improve Multi-Band Communications

This acoustic resonator easily configures via ferroelectric switching to filter wide-spectrum frequencies for 5G devices and tactical communication systems. The number of electronic devices that are internet-enabled has been increasing each year. Beyond mobile phones, all sorts of devices from thermostats to refrigerators connect with each other across a network called the Internet of Things (IoT). As more consumer electronics use internet communication, wireless networks must handle more users and devices and deliver higher speeds. Hence, the global market for 5G services, valued at more than $41 billion in 2020, continues to increase rapidly. Due to size and cost constraints, many consumer electronics must use resonators tuned to precise frequencies, which limits their functionality in 5G networks that integrate multiple frequency bands.

 

Researchers at the University of Florida have developed a digitally tunable acoustic wave resonator for processing signals in multi-band 5G communication systems. The resonator can tune and re-tune to different frequencies over a wide range, enabling 5G-integrated electronics such as radios and tactical communication devices.

 

 

Application

Digitally configurable acoustic resonator with wide-spectral coverage for 5G-capable devices

 

Advantages

  • Allows digital tuning of the resonator frequency, facilitating agile configuration of multi-band 5G radios via software
  • Covers cm- and mm-wave frequencies, enabling broad-spectrum 5G-carrier aggregation
  • Tunes via low voltages available on-chip, minimizing footprint for size-constrained electronic devices

Technology

This acoustic wave resonator is digitally configurable because of the ferroelectric properties of its transducer. The resonator consists of a substrate, a first electrode, a composite stack, and a second electrode. The ferroelectric properties of the scandium-doped aluminum nitride film layers in the composite stack allow an applied DC current to tune (and later re-tune) the transducer for particular frequencies. The inherent configurability of the resonator makes it suitable for signal processing in network-capable devices such as 5G radios or in tactical communication systems.

Patent Information:
Title App Type Country Serial No. Patent No. File Date Issued Date Expire Date
Digitally Tunable Acoustic Wave Resonators ORD/UTIL United States 17/173,919 11,799,448 2/11/2021 10/24/2023 3/24/2042