Samsung Electronics Qualifies Foundry Industry's First 32nm Low Power High-K Metal Gate Logic Process and Design Ecosystem
Samsung Foundry Demonstrates SoC Designed with 32nm LP HKMG Process Technology
Seoul, Korea, June 11, 2010 - Samsung Electronics, Co., Ltd., a global leader in advanced semiconductor solutions, today announced that its foundry business, Samsung Foundry, has qualified 32nm low-power (LP) process with high-k metal gate (HKMG)* technology. The process has successfully completed reliability testing at Samsung Foundry's 300-millimeter logic fabrication line, the S Line, in Giheung, Korea and, is now ready for production of customer designs. As the first to qualify 32nm LP HKMG logic process technology, Samsung Foundry is poised to begin volume manufacturing of chips designed to meet the media intensive, energy-efficient requirements of next-generation mobile consumer electronics.
Leveraging its deep sub-micron expertise in low power technology, Samsung Foundry, together with the IBM Joint Development Alliance (JDA), has tuned its 32nm LP HKMG gate-first process node to deliver a competitive, cutting-edge process platform with double the logic density of 45nm processes through minimized restrictive design rules.
"This result is another significant milestone in our strategy to provide leadership foundry process technology fully integrated with state-of-the-art design solutions for low power SOC design," said Stephen Woo, executive vice president and general manager, System LSI, Samsung Electronics. "Collaborating with several key partners, we have been able to take HKMG from development to implementation in a production environment. Our customers can now seamlessly integrate their design innovations with the most advanced 32nm LP HKMG process technology, design tools, IP and manufacturing to accelerate time to market for their leading edge mobile silicon solutions."
"Congratulations to Samsung on being the first foundry to demonstrate SOC's using high-k/metal gate technology. This important milestone represents the culmination of collaboration by the IBM technology development alliance to deliver the competitive, low power "gate first" high-k technology - ideal for the emerging next-generation mobile applications," said Gary Patton, vice president for IBM's Semiconductor Research and Development Center.
As part of the qualification process, Samsung Foundry designed and manufactured a 32nm LP system-on-chip (SoC) that shows 30 percent dynamic power reduction and 55 percent leakage power reduction when compared to the SoC design implemented at 45nm LP at the same frequency. Samsung Foundry was able to reach these significant power reduction numbers due to its gate-first HKMG implementation.
In developing the 32nm LP process, Samsung Foundry worked in close engineering partnership with its ecosystem partners. The partner IP successfully integrated and silicon proven in this SoC includes:
* ARM 1176 core
* ARM physical IP comprising of standard cells, memory compilers and I/Os
* Synopsys' USB 2.0 OTG
Samsung Foundry worked with EDA partners including Synopsys, Cadence Design Systems and Mentor to incorporate major advances into the design flow for 32nm LP such as:
- Advanced low power techniques including power gating, multi-threshold voltages, multi-channel lengths and adaptive body biasing techniques were used to reduce leakage power
- Statistical Static Timing Analysis (SSTA) was used to effectively address variation and reduce timing margins
- Various cell and chip level DFM techniques were used to improve manufacturability
Samsung's foundry customers benefit from this product proven design infrastructure and the continuous feedback loop that is unique to its foundry business.
With its extensive manufacturing expertise and continued development at leading-edge logic process technology, Samsung Foundry is focused on addressing the foundry market's advanced technology solution requirements. Samsung Foundry's 32nm LP HKMG process technology has been developed to offer customers shrinkable design rules and a smooth migration path to 28nm LP.
About Samsung Electronics' Foundry Business
Samsung Electronics' Foundry business is dedicated to support fabless and IDM semiconductor companies offering full service solutions encompassing design kits and proven IP to fully turnkey manufacturing to achieve market success with advanced IC designs by Foundry, ASIC and COT engagement. Currently in mass production at 45 nanometer (nm), Samsung Foundry is also preparing next generation 32/28nm and beyond process technologies by leveraging the deep expertise in advanced process technologies, design technologies, as well as a long, proven track record in high-volume manufacturing with its continued participation in the IBM Joint Development Alliance (JDA). For more information, please visit www.samsung.com/Foundry
About Samsung Electronics Co., Ltd.
Samsung Electronics Co., Ltd. is a global leader in semiconductor, telecommunication, digital media and digital convergence technologies with 2009 consolidated sales of US$116.8 billion. Employing approximately 188,000 people in 185 offices across 65 countries, the company consists of eight independently operated business units: Visual Display, Mobile Communications, Telecommunication Systems, Digital Appliances, IT Solutions, Digital Imaging, Semiconductor and LCD. Recognized as one of the fastest growing global brands, Samsung Electronics is a leading producer of digital TVs, memory chips, mobile phones and TFT-LCDs. For more information, please visit www.samsung.com
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* On January 29, 2007, IBM and its research partners introduced the high-k/metal gate innovation as the basis for a long-sought improvement to the transistor – the tiny on/off switch that serves as the basic building block of virtually all microchips made today. Using the high-k/metal gate material in a critical portion of the transistor that controls its primary on/off switching function enabled the development of 32nm chip circuitry that is designed to be smaller, faster, and more power-efficient than previously thought possible.