XBAR for 5G

The WaveX™ tool was initially used to design surface acoustic wave (SAW) filters. SAW filters traditionally supported lower-frequency bands with a good level of interference and co-existence blocking. However, the high accuracy of the WaveX design process resulted in better performing SAW filters. Since then, Resonant has been perfecting the use of the tool on higher-performing resonator technologies including temperature-compensated surface acoustic wave (TC-SAW) and, most recently, bulk acoustic wave (BAW) technologies.

BAW filters have traditionally been used at frequencies up to 2.7 GHz and in applications with difficult interference and coexistence challenges. Adapting these 4G filter structures to filter the higher-frequency 5G bands is a significant challenge. In addition, the bandwidth requirements for 5G, to realize HD video to the phone, also is significantly wider than previous generations of wireless technology. The percentage bandwidth the filter can deliver is now more than 10% (compare to 3-5% for 4G). Another important element is handling the high-power RF signal needed to accommodate the signal attenuation that occurs at these frequencies. The right technology for a 5G filter will support all three of these elements- high frequency, wide bandwidth, and high power - and so far, no BAW technology, except Resonant’s XBAR® technology, has been able to deliver all three.

In exploring the use of WaveX™ for BAW, Resonant developed a brand-new BAW resonating structure called XBAR®. In sample parts, XBAR® technology has shown it can filter at much higher frequency bands, surpassing the performance of other BAW filters. XBAR® technology is ideal for emerging 5G mobile devices that need wider bandwidth at higher frequency, and XBAR filters can be manufactured using existing fabrication processes for fast production.

WaveX™ simulations have shown that XBAR® technology can be used to develop filters for 5G New Radio (NR) devices operating in the 3 GHz to 6 GHz frequency range and also millimeter wave systems operating at 28 GHz and higher frequencies. Resonant has measured the performance of XBAR® technology up to 38 GHz.

For power handling, XBAR® filters have demonstrated more than 30 dBm (1W) power handling performance at the band edge. Power handling is important because as frequencies increase, transmit distances are reduced and power is increased to the RFFE to achieve transmit distance.

Rejection of adjacent frequency bands is another critical performance characteristic of filters especially for certain 5G bands that are adjacent to Wi-Fi bands. XBAR® filters have demonstrated Wi-Fi rejection at high frequencies to eliminate interference and allow for 5G and Wi-Fi co-existence in a phone or device. No other high performance integrated and low-cost solutions allowing for this co-existence have been announced.

Since invention, Resonant has continued to iterate its XBAR® filter, leveraging the WaveX™ platform. WaveX™ was used to simulate a prototype of a new XBAR® architecture that provides for the simultaneous operation of n77, n79, and 5GHz Wi-Fi using a n77/n79 diplexer and 5GHz Wi-Fi filter - the only such public simulation of a Wi-Fi/5G co-existence solution. This architecture has been confirmed as a preferred solution by a leading wireless operator, and the smaller design footprint will be critical to all handset manufacturers looking to deliver 5G handsets without sacrificing device size and battery life.

Resonant’s WaveX™ platform provides designs with superior performance for all RF filter technologies, which led to the development of XBAR®. With WaveX™ and XBAR®, the promise of next-generation wireless technology bandwidth and resulting enhanced user experience can be fulfilled.