Keysight Technologies has reported that Menlo Micro has chosen the company’s PathWave Advanced Design System (ADS) and Electromagnetic (EM) Design software to innovate advances in material science and develop a high-performance microelectromechanical system (MEMS) switch.
Menlo Micro needed to resolve customer challenges relating to accurate 3D electromagnetic simulation and integrated design, test and measurement workflows in the development of its new MM5130, an ultra-low-loss radio-frequency (RF) SP4T switch, to address high-power switching applications up to 26 GHz.
“In choosing design tools, we needed to consider the whole flow, from the schematic to the 3D simulations,” said Xu Zhu, Menlo Micro’s Director of Technology. “Our engineers need to be familiar with the tools, and that is one of the reasons why we chose Keysight’s PathWave Software as the core tool.”
“Menlo Micro designed a complex, multi-technology module comprised of a wide range of geometries from micron-scale MEMs to millimeter-scale PCBs,” stated Tom Lillig, general manager of Keysight’s PathWave Design business. “Leveraging Keysight’s fast, high capacity, 3D EM circuit simulators they achieved a successful implementation in one pass.”
With an eye on the time to market, Menlo targeted a short design cycle of three to four months.
Menlo Micro wanted to validate the performance of its new MM5130 switch early in the development process, so it chose to implement its PCB de-embedding algorithms into Keysight’s PathWave ADS software.
Menlo chose Keysight’s EM Design software, including EMPro and RFPro, integrated into the PathWave ADS platform, to create a familiar design environment for their engineering team. Because the engineers were constantly changing and adjusting the layout in PathWave ADS, a smooth workflow from circuit layout to 3D EM simulation was critical.
Keysight’s EMPro and RFPro enabled Menlo to make smooth translations from the 2D layout to the 3D model files. Keysight’s RFPro, with the SmartMount and Mesh Domain Optimization technologies, solved the mesh optimization challenges. Menlo Micro’s design flow includes tools from multiple vendors, so interoperability was critical.
As a result, Menlo Micro was able to shorten the design cycle of its new MEMS switch by 65 percent with measurements correlating closely to simulation. Previous projects of this scale could take up to nine months.