Yearly Archives: 2016

Brewer Science was honored by the Missouri Association of Manufacturers with a Made in Missouri Leadership Award (MMLA) for Sustainability Leadership. The award honors innovative Missouri manufacturers and leaders that are shaping the future of global manufacturing.

Brewer Science received recognition for the development and implementation of a robust and strategic environmental program, which led to a program that was certified Zero Waste to Landfill The impact of this certification reinforces Brewer Science’s commitment to the environment, both internally and externally.

“Environmental responsibility does not require an ROI – it is a simple truth and it adds value to our company, but more importantly to the global community,” said Tom Brown, Executive Director, Corporate Production and Sustainability. “Reducing the environmental footprint at Brewer Science has also had a positive impact on the region and in our approach to business by allowing us to contain costs through improved efficiencies.”

“In addition to monitoring and managing our waste, Brewer Science has continued a partnership with the community by helping stakeholders properly dispose of their waste,” said Matt Beard, Director of Integrated Management Systems. “By working with the City of Rolla, the Ozark Rivers Solid Waste Management District, the Missouri Department of Natural Resources, the Meramec Regional Planning Commission, and the Phelps County Commission, Brewer Science provides area residents with community collections that have enabled them to properly dispose of almost 811,000 pounds of waste over the past 11 years.”

Brewer Science is a developer and manufacturer of materials, processes, and equipment for the fabrication of semiconductors and microelectronic devices. With its headquarters in Rolla, Missouri, Brewer Science supports customers throughout the world with a service and distribution network in North America, Europe, and Asia. Brewer Science has earned the Zero Waste to Landfill certification from GreenCircle Certification LLC.

Cypress Semiconductor Corp. (Nasdaq:  CY) and Hackster today announced a global design competition that gives engineers the opportunity to prototype their innovative ideas that sense the world around us for use in the growing Internet of Things (IoT) market, home appliances, and consumer and industrial applications. The Sensing the World Challenge will use Cypress’s easy-to-use CY8CKIT-048 PSoC Analog Coprocessor Pioneer Kit as the development hardware platform. Hackster will select a winner from three regions—the Americas, Asia Pacific and Australia, and Europe and Africa—and each will receive an Oculus Rift virtual reality headset and development kit. Designers can sign up and find more information at www.hackster.io/contests/cypress-sensing-the-world-contest.

“People generally associate the IoT with connectivity, but most next-gen applications start with the ability to sense real-world conditions,” said Adam Benzion, co-founder and CEO of Hackster. “This new design challenge unleashes the imaginations of the worldwide Hackster community. Thanks to the Cypress PSoC Analog Coprocessor, they can develop a huge range of innovative applications with its mix of sensor input combinations.”

“I can’t wait to see what the creative minds of the Hackster community will develop with the rich, flexible analog resources they have to work with in this design contest,” said John Weil, vice president of MCU marketing at Cypress. “The PSoC Analog Coprocessor allows engineers to simply create cost-effective systems with precise, highly sensitive analog sensors. And our intuitive PSoC Creator integrated design environment enables rapid prototyping and design iterations with hardware and software flexibility.”

Initial proposals for the Sensing the World Challenge will be accepted through 11:55 p.m. Pacific Time on October 30, 2016, and 100 entries will be selected to receive the PSoC Analog Coprocessor Pioneer Kit to create a prototype of their idea. Projects will be due by 11:55 p.m. Pacific Time on January 8, 2017 and the regional winners will be announced on January 18.

Cypress will be demonstrating its PSoC portfolio, including the PSoC Analog Coprocessor, at World Maker Faire from October 1-2, 2016 at the New York Hall of Science in booth number 3206 in Zone 3.

The PSoC Analog Coprocessor integrates efficient and powerful signal processing with an ARM® Cortex® M0+ core and programmable analog blocks, including a new Universal Analog Block (UAB) that can be configured with GUI-based software components. This combination simplifies the design of custom analog front ends for multiple sensor interfaces by allowing engineers to update sensor features quickly with no hardware or host processor software changes, while also reducing BOM costs. For example, in home automation applications, engineers can easily configure the device to continuously monitor multiple sensors, such as temperature, humidity, ambient light, motion and sound, allowing the host to stay in a standby low-power mode. Future design changes to support new sensor types can also be easily implemented by reconfiguring the programmable analog blocks. More information on the PSoC Analog Coprocessor is available at www.cypress.com/PSoCAnalog.

The design of custom sensor interfaces is enabled by Cypress’s free PSoC Creator Integrated Design Environment (IDE), which simplifies system design by enabling concurrent hardware and firmware development using PSoC Components—free embedded ICs represented by an icon in the IDE. Engineers can easily configure the programmable analog blocks in the PSoC Analog Coprocessor by dragging and dropping components on the PSoC Creator schematic and customizing them with graphical component configuration tools. The components offer fully engineered embedded initialization, calibration and temperature correction algorithms.

Brewer Science is celebrating 35 years of innovation. Founded in 1981 by Dr. Terry Brewer, the company is known as an innovator and manufacturer of leading-edge materials and processes used in the semiconductor and microelectronics industry. The company’s in-depth knowledge and expertise in materials science, chemistry, physics, optics, modeling, and process integration distinguish Brewer Science from all other material suppliers worldwide. Dr. Terry Brewer is recognized as the inventor of anti-reflective coatings (ARC materials) and is widely regarded as a prominent global industry expert in semiconductor manufacturing.

Dr. Brewer has created an environment where employees are inspired to not just create a product, but have the freedom to be completely innovative. Under his leadership, Brewer Science has grown to be respected internationally and have a global network of highly trained people providing superior products, support, and service.

The technologies invented and manufactured at Brewer Science have been critical in the development of smaller, faster, and more powerful electronic devices. This year continues to be one of celebration as Brewer Science commemorates its 35th anniversary while highlighting its many technological breakthroughs in the microelectronics and related industries worldwide.

Dialog Semiconductor plc (XETRA:DLG), a provider of highly integrated power management, AC/DC power conversion, solid state lighting (SSL) and Bluetooth(R) low energy technology, today announced the appointment of Mary Chan to the company’s Board of Directors, effective December 1, 2016.

“Mary’s significant international experience in the wireless communications sector will perfectly complement the existing rich mix of skills and perspectives on our Board,” said Rich Beyer, Chairman of the Board, Dialog Semiconductor. “Her particular insight into the ways connectivity and the Internet of Things (IoT) are driving change across multiple industries by enabling the delivery of cloud-based services on connected mobile platforms will be especially valuable.”

Ms. Chan’s career has spanned executive leadership roles at some of the world’s most successful international firms, including AT&T, Alcatel Lucent, Dell Inc. and General Motors Corporation (GM). Most recently at GM, Ms. Chan served between 2012 and 2015 as President, Global Connected Consumers & OnStar Service USA. In this role, Ms. Chan headed the organization responsible for the development of GM’s Global infotainment product and launching 4G LTE connectivity across GM’s global vehicle brands, successfully implementing new business models to improve the connected car and infotainment experience. At Dell, between 2009 and 2012, Ms. Chan led the company’s Enterprise Mobility Solutions and Services business in the USA. Prior to this, at Alcatel-Lucent, Ms. Chan served as Executive Vice President of the company’s US 4G LTE Wireless Networks business.

Ms. Chan currently serves as an Independent Director on the Board of SBA Communications Corporation, a leading operator and owner of wireless communications infrastructure across North, Central and South America. In addition, Ms. Chan is also currently the Managing Partner at VectoIQ which serves a number of companies in the area of smart transportation. Previously she also served on the Boards of the Mobile Marketing Association and CTIA – The Wireless Association. She holds both Bachelor and Master of Science degrees in Electrical Engineering from Columbia University.

INVECAS Inc. and GLOBALFOUNDRIES announced today that INVECAS will provide IP and end-to-end ASIC design services as a part of the foundry’s FDXcelerator Partner Program, an ecosystem designed to facilitate 22FDX SoC designs for tomorrow’s intelligent systems. The collaboration accelerates the adoption of FDX technology in applications spanning Internet-of-Things (IoT), mobile, RF connectivity, and networking markets.

INVECAS will work closely with GLOBALFOUNDRIES’ technology teams to develop and verify a range of intellectual property (IP) for the company’s 22FDX process. Moreover, INVECAS will offer comprehensive ASIC design services to help customers realize SoC designs with high confidence and low risk.

“Our objective is to provide silicon-proven IP solutions and system-level expertise to address the difficult issues of design complexity facing ASIC designers today,” said Dasaradha Gude, chairman and CEO, INVECAS. “We are glad to be an initial partner in GLOBALFOUNDRIES’ FDXcelerator Program, a ground-breaking initiative to enable a broad range of customers and accelerate time-to-volume for 22FDX.”

“We are pleased to expand our strategic relationship with INVECAS and welcome them as an initial member of the FDXcelerator Partner Program,” said Alain Mutricy, senior vice president of product management at GLOBALFOUNDRIES. “In addition to the comprehensive portfolio of FDX-optimized IP, our customers can now access INVECAS’ full suite of services to realize their SoC designs on time and with highest quality.”

With the recent announcement of the company’s next-generation 12FDX technology, the FDXcelerator Partner Program builds upon GLOBALFOUNDRIES’ industry-first FD-SOI roadmap, a lower-cost migration path for designers on advanced nodes. By participating in FDXcelerator and continuing to expand its IP offering to support a wider range of FDX customers, INVECAS is well positioned as a leader in the adoption and growth of the FDX platform. Moreover, the FDXcelerator Partner Program broadens the technology collaboration between the companies, including tighter interlock around quality, qualification and development methodology.

By Paula Doe, SEMI

As the rate of traditional scaling slows, the chip sector looks increasingly to materials and design to move forward on multiple paths for multiple applications. Figuring out more effective ways to collaborate across silos will be crucial.

Source: IBM [IBM slide 6 in Strategic Materials Conference deck]

Source: IBM [IBM slide 6 in Strategic Materials Conference deck]

  1. Paradigm shift requires co-optimization

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“Scaling has hit a wall, and there is no longer any single path forward,” noted Larry Clevenger, BEOL Architect and Technology Definition, IBM Research, at the SEMI Strategic Materials Conference 2016 (September 20-21). “The materials set we use in the middle and back end of line is running out of steam. We need new materials and design co-optimization.”  He noted EUV would much improve the critical tight pitch areas for the memory and BEOL for 7nm-5nm logic. But reducing the parasitics in the metal interconnect in middle of the line and BEOL will also be critical, with good results demonstrated from new materials like Si:P and Ge:Ga meta-stable alloys, cobalt instead of tungsten, self-forming encapsulation of copper by cobalt, and airgaps, all of which would require optimization of an ecosystem of appropriate cleaning, deposition and wet process technologies for integration. Changing the design to route the critical paths directly up to higher wiring levels where the wires are larger would also help reduce resistance.

“It’s a paradigm shift that what was once a process deviation is now an excursion,” said Archita Sengupta, Intel senior technologist, noting the need for new specialized tools to measure, monitor and control the process to detect ever tinier defects sooner. “We need more proactive cooperation across the supply chain for bottom up control of quality from suppliers.”

Showing impressive examples of imaging and computation enabling doctors to reduce errors in breast cancer detection by 85 percent, and even to operate on a beating heart, using Nvidia GPUs and artificial intelligence, Nvidia’s director of Advanced Technology John Hu noted, “We are at a real inflection point for demand for more compute power, and we can’t get there by just process scaling any more. We are going to have to rely on new architectures to rescue us from the increasingly imperfect reality of materials and processes.”

While almost every speaker stressed the increasing need for the different segments of the supply chain from materials to design to work more closely together to move technology forward along many new paths, the materials suppliers in the audience felt that progress could be better to make this happen. Some audience members talked among themselves of now being invited more often into the fabs to discuss material development, but still not being told much detail about the key target parameters. Material suppliers in the audience raised the issues of the time and expense needed to qualify their second sources for raw materials and precursors, to get the needed environmental certifications, and to find access to the expensive exotic multi-technology metrology tools capable of finding contaminates too small to see with conventional methods, before they could even bring in any potential material to be evaluated for use several years in the future.

Although speakers kept referring to the past Golden Age of Moore’s Law of regular two-year dimensional scaling, before the proliferation of alternatives, Tim Hendry, retiring Intel VP, Fab Materials, pointed out that it hadn’t really seemed like a Golden Age at the time. “As I remember, we thought it was pretty hard back then too.”

  1. Look to self-aligned and selective processes as scaling boosters

As lithography scaling slows down, new approaches will make creative use of deposition and etch to keep improving pattern resolution. “14nm is a real sweet spot technically for lithography that will be with us for a long time,” noted Anton DeVilliers, Tokyo Electron America director of Patterning Technology, suggesting a toolkit of assorted self-alignment and selective deposition and etch processes likely to see increasing use as resolution boosters as an alternative to pushing the lithography, such as collars at key points to protect the pattern, or self aligned patterning by selective etching.

Adding a protective ALD collar holds a key region open during etch to widen the process window and prevent shorts from process variation in tight pattern areas.

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ALD snap collar holds the critical part of M1 pattern open to widen window in LELELE process…

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So that overlay variation that would typically create a short…

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Instead creates the desired pattern. Source: TEL

Using materials with different etch selectivity for different parts of a pattern, such as for alternate lines, enables the creation of a self aligned pattern at higher resolution than the lithography.  Different etch selectivity in alternate metal tracks could also reduce the number of exposure passes and improve overlay tolerance. “For 5nm nanowires, we’ll have to use selective ALD and ALE, controlled by self assembling monolayers,” noted DeVilliers. “We’ve done each of these steps on a tool, but now the challenge is to put them all together.”

  1. Progress on 3D alternatives

“To maintain the pace of progress we’ll have to change everything—we can’t do it with Moore’s Law,” said Bill Bottoms, chairman and CEO, Third Millennium Test Solutions, updating on the international effort to create a Heterogeneous Integration Roadmap. “Future progress will come from bringing active elements closer together through integration at the system level, with interconnect with photonics and plasmonics.” The aim is to map future needs to better enable precompetitive collaboration. The first edition of the roadmap is now slated to come out in March.

SMC-Image6

CEA-Leti researchers meanwhile are reporting good progress on lowering the temperatures of the various processes needed to build a second chip directly on top of a first, for monolithic 3D CMOS-on-CMOS integration.  Performance of the bottom chip degrades if the process temperatures for the top chip are >500°C, mainly because the NiPt silicide deteriorates, but replacing the NiPt with a more stable NiCo and adding an Si cap looks promising to increase stability. The 8nm active active layer for the top device is bonded atop the bottom device at room temperature and annealed 300C. Nanosecond laser thermal annealing and low temperature solid phase epitaxy regrowth help bring down temperatures for dopant activation. Cycles of deposition and etch replace selective epitaxy for the source and drain, while different precursors reduce process temperatures to 500-550C. “Later this year at IEDM we’ll demonstrate top CMOS made at 500°C with these developments,” said Philippe Rodriguez, CEA-Leti research engineer.

  1. Get used to the slow growth world 

The semiconductor industry will see silicon demand (MSI) pick up from this year’s 0.6 percent increase to  ~3.8 percent growth in 2017, and ~6.3 percent in 2018, as some uncertainty about interest rates and government policy in major countries resolves, according to the econometric semiconductor forecast from Hilltop Economics and LINX Consulting. “We got comfortable with 3 percent GDP growth in the world that we sell chips into, but since the 2009 recession we are only seeing about 2.4 percent growth,” said Duncan Meldrum, chief economist, Hilltop Economics. He noted that economists keep saying the world will get back to its regular 3 percent growth next quarter or year, but it hasn’t happened, probably because high government debt levels in most major economies tends to reduce growth by about reduces it. Silicon demand grows a little faster than GDP, but its trends generally track that global growth number more than in the past as the electronics industry matures.

  1. Wafer level fan out will shake up package materials sector

Now that it appears the 40 to 50 percent improvement in performance in the newest Apple A10 processor is largely from its wafer-level fan out packaging from TSMC, demand for the packaging approach is ramping fast. “This is one of the fastest ramps we’ve seem for a package in a long time,” said TechSearch International president Jan Vardaman. “It’s a very disruptive technology that will have a big impact on the industry.” The thinner, lower-cost packaging approach is also showing up in RF and audio codec chips in mobile phones, with  ~2 billion units just in Samsung and Apple phones, potentially bringing big changes to the packaging materials market. Laminate substrate suppliers will see demand plunge, copper post suppliers will see little change, and makers of wafer-level dielectrics could potentially see 3X growth in volume. “But don’t think you’ll see that in revenue, since customers will really beat the prices down.”

And in a final note, the gathered materials sector paused in a moment of silence for Dan Rose, who passed away on September 19.  Dan was a well-known market researcher and founder of Rose Associates with a focus on materials market data.

Originally published on the SEMI blog.

IC Insights recently released its September Update to the 2016 McClean Report. This Update included Part 2 of an extensive analysis of the IC foundry business. An excerpt from the September Update, describing foundry sales by feature size, is shown below.

Figure 1

Figure 1

TSMC has long been the technology leader among the major pure-play foundries. As shown in Figure 1, 54% of TSMC’s 2016 revenue is expected to come from <40nm processing. GlobalFoundries, which has dedicated a large portion of its capacity to making advanced processors over the past few years, also generates a large portion of its sales based on leading-edge process technology and feature sizes. In 2016, 52% of GlobalFoundries’ sales are forecast to come from <40nm production.

Although GlobalFoundries and TSMC are forecast to have a similar share of their sales dedicated to <40nm technology this year, TSMC is expected to have almost 6x the sales volume at <40nm as compared to GlobalFoundries in 2016 ($15.6 billion for TSMC and $2.6 billion for GlobalFoundries). In contrast, SMIC only entered initial production of its 28nm technology in 4Q15, more than three years after TSMC first put its 28nm process into production.

Because TSMC has a very large percentage of its sales targeting <40nm production, its revenue per wafer is forecast to increase at a CAGR of 3% from 2011 through 2016 as compared to a -1% CAGR expected for the total revenue per wafer average of GlobalFoundries, UMC, and SMIC over this same timeperiod. Only 2% of SMIC’s 2016 sales are expected to come from devices having 28nm feature sizes (the company does not offer a finer feature size at this time), which is the primary reason its revenue per wafer is so low as compared to TSMC and GlobalFoundries.

It is interesting to note that the increase in pure-play foundry sales this year is forecast to be almost entirely due to <40nm feature size device sales (Figure 2). Although it is expected to represent 60% of total pure-play foundry sales in 2016, the ≥40nm pure-play IC foundry market is forecast to be flat this year. In contrast, the leading-edge <40nm pure-play foundry market in 2016 is expected to surge by 23%, increasing by a hefty $3.6 billion.

Figure 2

Figure 2

Synopsys, Inc. (Nasdaq:  SNPS) today announced that TSMC is recognizing Synopsys with three “2016 Partner of the Year” awards for Interface IP and joint development of 7-nanometer (nm) mobile and HPC design platforms. Synopsys and TSMC have been collaborating for more than 16 years, most recently to accelerate the adoption of FinFET technology for optimum power, performance and area for the 7-nm process. This is the 6th consecutive year Synopsys has received both IP and electronic design automation (EDA) accolades from TSMC.

“TSMC and Synopsys share a common goal to provide an extensive portfolio of proven IP and design tools supporting TSMC’s latest process technologies,” said Glenn Dukes, vice president of strategic alliances and professional services at Synopsys. “Our strong engineering collaboration with TSMC on its 7-nanometer FinFET process results in a proven path that designers can adopt to help achieve their time-to-market goals.”

“Through OIP collaboration, TSMC and Synopsys continue to provide our mutual customers with certified design implementation tools and high-quality IP optimized for TSMC’s leading process technologies,” said Suk Lee, TSMC senior director of the Design Infrastructure Marketing Division. “With its DesignWare IP and Galaxy Design Platform, Synopsys helps companies achieve their design goals and quickly ramp into volume production.”

Today during the NXP FTF China Tech Forum keynote, NXP Semiconductors (NASDAQ:NXPI) kicked off its 10th year anniversary celebration since its founding as a standalone semiconductor company, with NXP Chief Executive Officer, Rick Clemmer, highlighting the key trends that are driving the company’s growth – ADAS, Internet of Things (IoT), security, automotive and payments.

“As NXP celebrates a decade, we’re reminded of how important innovations in security and connectivity, key partnerships and ecosystem convergence has been in both the evolution of a smarter world and our company growth,” said Clemmer. “We are celebrating today with customers, employees and partners, but more importantly we are looking towards the future – a future of more secure connections for a smarter world. Here at NXP FTF China, we are demonstrating our vitality notably in automotive, IoT, payment and transit technologies.”

NXP FTF China is taking place at the Shenzhen Intercontinental Hotel, September 28-29. At the event, the company announced key collaborations and unveiled new solutions for IoT, automotive and smart kitchens. Announcements include:

  • Establishing Security Standards for Smart Cars in China with Cross-sector Collaborations

    NXP announced it is collaborating with Changan Automobile and Neusoft to establish the China Auto Security Common Interests Group (CIG). The group brings together a hardware-based industry cooperative organization for automotive security with local automotive and software partners in the global market. CIG will adopt “NXP 4 plus 1 security framework” – the highest level of car information security today. The CIG will work together to develop comprehensive industrial solutions and will collaborate to establish industry standards to contribute to the innovation of China’s automotive industry.

  • Driving Mobile Transit and Contactless Payment in China

    NXP and Xiaomi Inc. today announced they are successfully deploying best-in-class technologies to implement secure, convenient mobile transit experiences countrywide across China’s popular metro stations and public bus lines. Since initial launch of the mobile transit services in June, activation rates grew more than 15 percent in Shanghai and more than 20 percent in Shenzhen among commuters. And with Xiaomi’s recent launch of Mi Pay, featuring NXP’s embedded secure element (eSE) technology, consumers will benefit from the highest level of security for transactions from both bank and transportation accounts.
  • NXP and Midea Demonstrate New Smart Kitchen Appliances

    NXP is collaborating with Midea to achieve breakthrough R&D innovations in smart kitchen appliances. NXP has brought revolutionary changes to Midea products through technological innovations: the semiconductor-heating cube demonstrated at the Tech Forum is the first result of this cooperation. With a sleek appearance, it features the MHT1004N solution based on NXP’s RF technology and is small in volume, lightweight and easy to carry, offering users with a more convenient cooking experience. As a major milestone in NXP’s cooperation in R&D of smart kitchen solutions in China, the launch of the semiconductor-heating cube heralds broader cooperation between the two parties in the field of smart home appliances.
  • Integrated Innovation to Push New Solutions for Secure Connected cars

    NXP announced its expansion of the industry leading MagniV microcontrollers product line and introduced a broad portfolio of hardware, software and integrated motor control solutions designed to dramatically speed time to market.  The new integrated solution would radically simplify system development and shorten design cycles.

    In addition, NXP also extended its leadership in secure car access technology to car-side systems with the introduction of the NJJ29C0 Low Frequency transceiver. As a leader in advanced key fob designs, NXP now enables full system solutions that combine longer-range performance and enhanced convenience for end-users, together with reduced costs, faster time-to market and greater design freedom for OEMs and their tier one suppliers.

  • New Innovative Technologies Designed in China, Built in China, For China

    At NXP FTF China, NXP officially unveiled the i.MX 6ULL – the lowest power ARM® Cortex-A7-based applications processor in the market.  The i.MX6 ULL processor, designed for the growing IoT consumer and industrial, mass markets, delivers up to 30 percent more power efficiency than its nearest competitors and is available at breakthrough prices.

    NXP also announced it is expanding the Kinetis E Series with KE1xZ and KE1xF ARM® Cortex® -M based MCU families to bring higher performance with greater memory densities and robust IP integration to the series making them ideal for high-end home appliances, motor control and smart lighting applications.

    NXP today introduced the industry’s first automotive 15W wireless charging solution, qualified to meet stringent automotive and industrial grade requirements. Compatible with WPC Qi and PMA charging standards, this complete solution allows automakers to easily transition from 5W to 15W capabilities, giving drivers a faster in-vehicle charging experience for mobile phones, tablets and wearables.

    In addition, the company announced that Cannice Technology, an original design manufacturer based in China, has unveiled a production-ready true wireless earbuds design.

INVECAS Inc., an IP, ASIC and embedded software solutions provider, and GLOBALFOUNDRIES today announced the availability of foundation IP for GLOBALFOUNDRIES’ 14nm FinFET technology. The silicon-proven IP from INVECAS is optimized for the performance, power, and area requirements of high-performance “all-the-time” applications such as high-end smartphones, networking, server, and graphics processors. This application-tailored library enables customers to rapidly develop high-performance and power-efficient systems.

INVECAS IP taps the benefits of FinFET to deliver more processing power in a smaller footprint for the most demanding applications. The comprehensive IP portfolio includes foundation IP such as general-purpose I/O (GPIO), memories, standard cell libraries, and a full set of interface and analog IP solutions.

“GLOBALFOUNDRIES’ 14LPP offers a silicon-proven solution for customers seeking to differentiate their products and accelerate time-to-volume of designs on complex technologies,” said Alain Mutricy, senior vice president of product management at GLOBALFOUNDRIES. “We further enhance our technology through early engagement with ecosystem partners like INVECAS, to ensure a robust infrastructure with a low-risk, silicon-proven, and efficient design strategy. Our strategic relationship with INVECAS provides our customers with the 14LPP performance and power optimized IP platforms to push their SoC designs to new levels and deliver the highest performance silicon for a broad set of applications.”

“INVECAS is dedicated to overcoming SoC design challenges with optimized IP and silicon realization services on GLOBALFOUNDRIES’ processes,” said Dasaradha Gude, chairman and CEO of INVECAS Inc. “By combining our proven system-level expertise with GLOBALFOUNDRIES’ advanced 14nm FinFET technology, we are uniquely positioned to provide complete solutions for the compute, communication, mobile, and automotive markets.”

INVECAS will showcase its silicon-proven IP solutions during GLOBALFOUNDRIES Technology Conference (GTC) on September 29 at the Sofitel Munich Bayerpost in Munich, Germany.