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STMicroelectronics Introduces a New Family of Single- and Two-Axis MEMS Gyroscopes

June 8, 2009

MEMS market leader applies field-proven performance and reliability to gyroscopes for enhanced user interfaces, gaming, GPS navigation, and camera-image stabilization

GENEVA, June 8 /PRNewswire-FirstCall/ — STMicroelectronics (NYSE: STM), the leading supplier of MEMS for consumer and portable applications(1), has introduced a new family of single- and multi-axis MEMS (Micro-Electro-Mechanical Systems) gyroscopes. Underpinned by the Company’s market-proven micromachining technology, which utilizes the unique mechanical properties of silicon by producing structures within the semiconductor chip to measure movement, ST’s gyroscopes deliver superior performance and reliability for angular-motion detection in human-machine interface applications, personal and car navigation systems, and image stabilization for digital still and video cameras. Gyroscopes complement acceleration sensors in ever more popular man-machine interfaces, making gaming and remote-pointing more exciting, enhance car navigation applications for dead-reckoning and/or map-matching, and counteract digital video or still camera shaking for sharper shots.

ST’s complete family of single-axis (yaw) and two-axis (pitch-and-roll, pitch-and-yaw) MEMS gyroscopes offers the industry’s widest full-scale range, from 30 to 6,000 dps (degrees per second). The innovatively designed sensors can provide two separate outputs for each axis at the same time – an unamplified output value for general detection of angular motion and a 4x amplification for high-resolution measurements that enhances design flexibility and the user experience.

ST’s new gyroscopes boast excellent stability over a wide temperature range and time, with variation typically lower than 0.05dps/degrees C for zero-rate level, eliminating the need for further temperature compensation in the application. Measurement precision is ensured with the negligible level of noise that affects the output signal (0.014dps/sqrt(Hz) at 30dps full-scale).

The high-performance MEMS gyroscopes are resistant to mechanical stress thanks to the robust process already successfully applied to the several hundred million ST accelerometers sold in the market and are able to operate with any supply voltage in the range of 2.7 to 3.6 V. The 5×5 mm LGA package, together with the innovative design approach, ensures a high level of integration in space-constrained designs as well as better performance and soldering stability compared with bulkier ceramic packages.

Samples of the complete family of MEMS gyroscopes (yaw, pitch-and-roll, and pitch-and-yaw) with full scales ranging from 30dps to 6000dps are available now and mass production is expected to start in Q3 2009. Examples include LPR503AL, a two-axis pitch-and-roll gyroscope with 30dps and 120dps full scales, and LPY550AL, a two-axis pitch-and-yaw gyroscope with 500dps and 2,000dps full scales.

Unit pricing is $2.5 for quantities of tens of thousands pieces. For further information on ST’s complete MEMS portfolio go to www.st.com/mems.

About STMicroelectronics

STMicroelectronics is a global leader in developing and delivering semiconductor solutions across the spectrum of microelectronics applications. An unrivalled combination of silicon and system expertise, manufacturing strength, Intellectual Property (IP) portfolio and strategic partners positions the Company at the forefront of System-on-Chip (SoC) technology and its products play a key role in enabling today’s convergence markets. The Company’s shares are traded on the New York Stock Exchange, on Euronext Paris and on the Milan Stock Exchange. In 2008, the Company’s net revenues were $9.84 billion. Further information on ST can be found at www.st.com.

Notes to Editors:

There are three main types of angular motion: yaw is rotation around the vertical axis; roll is rotation around the front-to-back axis and pitch is the rotation around the side-to-side axis.

Dead reckoning, or assisted satellite navigation, is a feature that enhances a navigation system’s ability to estimate its current location without direct contact with the GPS satellites it would normally use. The feature is valuable in situations where the navigation system is unable to receive signals from GPS satellites, such as inside road tunnels or buildings. Dead reckoning is also useful as an energy-saving technique, since the navigation system can estimate small changes in location from a previous position using more power-efficient MEMS technologies while periodically turning off the less efficient GPS circuits.

(1) iSuppli December 2008

SOURCE STMicroelectronics


Source: newswire