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NEWSROOM: From the founders of RF SOI


Peregrine Semiconductor’s UltraCMOS® RFICs Flying in Globalstar Communication Satellites

San Diego, California, Mar. 25, 2013 Peregrine Semiconductor Corporation (NASDAQ: PSMI), a fabless provider of high-performance radio frequency integrated circuits (RFICs), today announced that its UltraCMOS®Phase Locked Loop (PLL) frequency synthesizer and prescaler devices are designed into six Globalstar mobile communication satellites that were launched into orbit on February 6. Built by Thales Alenia Space in France, the low-Earth orbit satellites transmit audio and data communications for Globalstar’s mobile voice and data customers worldwide. Peregrine’s PLL and prescaler enable communication in sixteen C- and S-band transponders in the system, which connects end users with terrestrial communication networks via vehicle-mounted mobile devices, as well as fixed terminals, such as those used for rural telephony. The Peregrine devices feature extremely low phase noise and Single Event Effect (SEE) immunity—attributes enabled by the insulating properties of UltraCMOS process technology—as well as low power, small form factor, and light weight.

“Our products have nearly 20 years of commercial space flight heritage in some of the  most high-profile missions, and we’ve considered Thales Alenia Space an important partner in our endeavor to provide market-leading RF performance in the most demanding radiation-rich environments,” said Dave Shepard, vice president of Peregrine Semiconductor’s High-Performance Solutions business unit.  “We’re delighted that Peregrine’s PLL and prescaler were selected for the Globalstar satellites and that UltraCMOS, with its inherent radiation-induced latchup immunity, continues to be the technology of choice for this, or any, space application.”

Single Event Effects are errors that are caused by naturally-occurring space-based radiation. There are two primary types of SEEs. Single Event Upsets (SEUs) are non-destructive and can be corrected. Single Event Latchups (SELs), on the other hand, are often catastrophic, resulting in permanent damage and requiring, at a minimum, a power-down to recover. SELs can occur when a high- energy particle strikes a semiconductor device, causing a short circuit from power to ground within the device. RFICs manufactured using UltraCMOS technology do not contain the bulk parasitics found in regular CMOS devices, making latchup impossible.

Peregrine’s UltraCMOS technology is an advanced RF Silicon-On-Insulator process that utilizes a synthetic sapphire substrate—a near-perfect electrical insulator. This substrate enables low parasitic capacitance, high signal isolation, excellent broadband linearity, and inherent SEL immunity. These attributes make UltraCMOS well suited for high-reliability applications, such as commercial satellites. For more information about Peregrine Semiconductor’s high-reliability products, visit http://www.psemi.com.

About Peregrine Semiconductor

Peregrine Semiconductor (NASDAQ: PSMI) is a fabless provider of high-performance radio frequency integrated circuits (RFICs). Our solutions leverage our proprietary UltraCMOS® technology, an advanced RF Silicon-On-Insulator process. Our products deliver what we believe is an industry-leading combination of performance and monolithic integration, and target a broad range of applications in the aerospace and defense, broadband, industrial, mobile wireless device, test and measurement equipment, and wireless infrastructure markets. Additional information is available at http://www.psemi.com.

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The Peregrine Semiconductor name, logo, and UltraCMOS are registered trademarks of Peregrine Semiconductor Corporation in the U.S.A., and other countries. All other trademarks mentioned herein are the property of their respective owners.