UMC Fabricates World's Highest Frequency Silicon Circuit Using CMOS -
192-GHz Voltage-Controlled Oscillator

Push-push Voltage-Controlled Oscillator (VCO) designed by the University of Florida reaches 192-GHz Operating Frequency

HSINCHU, Taiwan, February 21, 2006 -- UMC (NYSE: UMC; TSE: 2303), a world leading semiconductor foundry, today announced that it has fabricated a push-push Voltage-Controlled Oscillator (VCO) with an operating frequency of 192-GHz using its 0.13um RFCMOS process technology. 192-GHz is the highest operating frequency for any silicon-based circuit to date. The chip was developed by the Silicon Microwave Integrated Circuits and Systems Research Group (SIMICS), Department of Electrical and Computer Engineering at the University of Florida, Gainesville, which also introduced a record setting 105-GHz VCO produced by UMC in June 2005 (see story at http://www.umc.com/English/news/20050620.asp).

VCOs are used in virtually all RF and wireless systems. High frequency oscillators such as the 192-GHz VCO, manufactured by UMC, can potentially be used for advanced remote sensing and imaging applications to accomplish chemical detection, detection through fabric, imaging through fog and clouds, and the detection of skin cancer.

Oscillators are known for generating signals at normal operating frequencies and can be pushed to 2X, 3X, 4X the frequency, etc. However, signals at these higher frequencies are often too weak to be effective. In push-push VCOs, because the VCO core operating frequency is one half of the output frequency, besides higher device gain, varactor and capacitor Q factors are also higher, while the transmission line loss is lower--resulting in a stronger signal. The VCO provides output power of ~-20 dBm and phase noise of ~-100 dBc/Hz at 10 MHz offset, while consuming 11 mA from a 1.5-V supply. This work has been supported by DARPA and is published in a paper authored by Changhua Cao, Eunyoung Seok and Kenneth O in the Feb. 16th issue of IEE Electronics Letters.

"UMC's proven RFCMOS technology is currently being used to power a broad range of advanced wireless applications," said Patrick T. Lin, chief SoC architect, system & architecture support at UMC. "The VCO developed by the University of Florida also demonstrated that UMC's RFCMOS technology is well suited for designs that require extreme levels of performance. We are excited about the technological achievements that we have accomplished with the university to date and look forward to offering the fruits of these developments to the mainstream RF design community."

"This is particularly exciting because we produced the VCO using a 0.13-um CMOS process," said Professor Kenneth O. "We also have a 140-GHz fundamental VCO running in our lab, which has been fabricated using UMC's 90-nm logic process. It should be a straightforward matter to turn this into a push-push VCO to generate ~280-GHz signal. Furthermore, if a 65-nm process is used, we can probably reach 350-400 GHz. Generating a THz signal in CMOS technology is not far off."

About UMC
UMC (NYSE: UMC, TSE: 2303) is a leading global semiconductor foundry that manufactures advanced process ICs for applications spanning every major sector of the semiconductor industry. UMC delivers cutting-edge foundry technologies that enable sophisticated system-on-chip (SoC) designs, including 90nm copper, 0.13um copper, and mixed signal/RFCMOS. UMC is also a leader in 300mm manufacturing; Fab 12A in Taiwan and Singapore-based Fab 12i are both in volume production for a variety of customer products. UMC employs approximately 12,000 people worldwide and has offices in Taiwan, Japan, Singapore, Europe, and the United States. UMC can be found on the web at http://www.umc.com.

Note From UMC Concerning Forward-Looking Statements
Some of the statements in the foregoing announcement are forward looking within the meaning of the U.S. Federal Securities laws, including statements about future outsourcing, wafer capacity, technologies, business relationships and market conditions. Investors are cautioned that actual events and results could differ materially from these statements as a result of a variety of factors, including conditions in the overall semiconductor market and economy; acceptance and demand for products from UMC; and technological and development risks.



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