Yearly Archives: 2015

The European Commission has approved under the EU Merger Regulation the acquisition of Broadcom Corporation by Avago Technologies Limited. Both companies are global manufacturers of semiconductors. The Commission concluded that the merged entity would continue to face effective competition in Europe.

Commissioner Margrethe Vestager, in charge of competition policy, said: “Thanks to very good cooperation with the companies the Commission has been able to approve this multi-billion dollar takeover within a very short space of time while preserving effective competition in this crucial high-technology sector.”

The Commission’s investigation showed that the portfolios of the companies are mainly complementary since Broadcom makes “off-the-shelf” chips for the broadband and connectivity market segments, while Avago makes custom-built chips for special applications in the analog wireless integrated circuits, enterprise, storage and industrial segments.

Nevertheless, the Commission had some concerns about the vertical relationship created by the transaction, since Avago supplies certain intellectual property (technology for allowing fast data transmission between chips) to some of Broadcom’s competitors. The Commission’s concern was that after the takeover Avago could have had an incentive to withhold this intellectual property in order to extend the merged entity’s leading market position in the so-called “switch chips” market.

However, already during the Commission’s assessment of the case, Avago addressed these concerns by entering into commercial agreements with other “switch chip” manufacturers. These agreements will ensure that other “switch chip” manufacturers will continue to have access to the necessary intellectual property on reasonable terms. Thanks to this up-front solution, the Commission has been able to unconditionally clear the proposed transaction, which was notified on October 2, 2015.

Related news: 

Avago Technologies acquisition of Broadcom creates a new semiconductor powerhouse

Historic era of consolidation for chipmakers

Lattice Semiconductor Corporation, a manufacturer of programmable logic devices, has appointed Glen Hawk as COO.

This is a new position for the Company. Mr. Hawk previously served as the Company’s Corporate vice president, Chief Marketing Officer.

In his new role as COO, Mr. Hawk will be responsible for all aspects of the Company’s operations, sales and marketing functions. He will report directly to the Company’s President and CEO, Mr. Darin G. Billerbeck. Darin G. Billerbeck, President and CEO, said, “We are pleased that Glen has agreed to take on the expanded role of COO. His extensive semiconductor industry experience, market insight and drive make him ideal for this position. Glen’s direct role in helping companies to create value through growth and market differentiation will continue to benefit Lattice as we move forward.”

Glen Hawk, COO, said, “I joined Lattice Semiconductor earlier this year because I was excited about the Company’s long-term prospects. I look forward to partnering with Darin and the leadership team to accelerate growth by delivering compelling FPGA, ASSP and millimeter wave solutions to our customers.”

Glen Hawk joined Lattice Semiconductor in May 2015 as Corporate vice president, Chief Marketing Officer after serving as vice president and General Manager of the NAND Solutions Group at Micron Technology. During his time at Micron, Mr. Hawk directed the activities of 1,200 employees. Before Micron, Mr. Hawk was vice president, General Manager of the Embedded Business Group at Numonyx and was at Intel for 22 years in both engineering and business functions, including General Manager of Intel’s Flash Products Group. Mr. Hawk started his career at Monolithic Memories developing Programmable Array Logic technologies.

Vistec Electron Beam GmbH, a supplier of electron-beam lithography systems, announced that it has established a show room facility in Schaumburg, IL to promote and demonstrate their Variable Shaped Beam systems specifically for the US and North America market.

The show room facility in Schaumburg is designed to demonstrate the functionality and operation of Vistec’s ebeam equipment and to provide an insight into its various applications. The key component of the facility is a fully operational Vistec SB254 electron-beam lithography system, installed in a clean room of 970sqft., supplemented by a set of process and measurement equipment for standard sample processing.

“We are very pleased to be able to offer such a demonstration capability to potential North America market customers. The availability of the show room facility shall manifest our commitment to this important high technology region, it will foster our activities to better understand customer needs and shall help to provide tailored solutions to their specific requirements,” said Wolfgang Dorl, General Manager of Vistec Electron Beam.

Cambridge CMOS Sensors (CCS), a semiconductor company with gas sensor solutions to monitor the local environment, today announced that it has been crowned winner of the Product of the Year category at this year’s National Microelectronics Institute (NMI) Awards, held at the Grange Tower Bridge Hotel in London.

CCS was awarded the Product of the Year award for their excellent approach to understanding market needs, customer acceptance and reliability methodology for their CCS801 sensor for Indoor Air Quality Monitoring. This is the second successive year that CCS have been honoured in the annual NMI Awards, after winning last year’s Innovation Award.

The 2015 NMI awards are designed to celebrate the year’s key electronics innovations, people and companies from across the UK and Ireland. It has been run as an annual event since 2001. The fourteen categories also included awards such as Manufacturing Supplier of the Year, University Research Group of the Year, Company of the Year and Research Collaboration Award.

Nat Edington, CEO, at CCS said, “We are honoured to have received this award and to be recognised by NMI for the second year in a row. The past 12 months have been a transformational period for CCS and everyone has worked incredibly hard to ensure we capitalise on the great opportunities in front of us. I would like to thank all of our employees for their efforts, which have enabled us to win this award.”

Demand for LTPS TFT LCD shipments rose 30 percent in September 2015 to reach 51.6 million units, due to strong demand from Apple and Chinese brands. Total smartphone panel shipments grew 4 percent month over month to reach 160 million units in September 2015. While amorphous silicon (a-Si) thin-film transistor (TFT) liquid-crystal display (LCD) panels continue to lead the smartphone display market, low-temperature polysilicon (LTPS) TFT LCD panel shipment share is growing, according to IHS Inc., a of critical information and insight.

“TFT-LCD, based on a-Si substrate, has been the leading panel technology for mobile phones because it is easy to manufacture and costs less to produce than other display technologies. However, since Apple adopted LTPS for its popular iPhones, demand for the new technology has continued to increase,” said Brian Huh, senior analyst for IHS Technology. “While LTPS panels cost greater, they boast lower power consumption and higher resolution compared to a-Si LCD panels. Greater demand for higher definition screens, especially in China, has also increased the adoption of LTPS LCD mobile phone displays.”

Based on the latest information in the IHS Smartphone Display Shipment Trackerthe market share for the a-Si TFT LCD panel fell 10 percent month over month, but the panel still comprised the majority of smartphone display shipments, reaching 79.6 million in September 2015. Active-matrix organic light-emitting diode (AMOLED) panel shipments grew 7 percent to reach just 25 million units.

As a point of differentiation in the smartphone display market, Samsung Electronics adopted AMOLED-based LTPS displays in 2009. At that time Samsung Display was not looking to expand its customer base because Samsung Electronics digested almost all of the company’s AMOLED capacity. However as Samsung Electronics’ AMOLED smartphone business began to decline last year, Samsung Display has been expanding its customer lineup. “Since the end of last year, Samsung Display has been actively and aggressively promoting AMOLED displays to other electronics companies, especially in China, and AMOLED panel shipments for Chinese brands have increased remarkably since September,” Huh said.

Year-over-year large-area display shipments are forecast to fall 5 percent, reaching 682 million units in 2015. This decline in unit shipments will be offset by an increase in large area thin-film transistor (TFT) liquid crystal display (LCD) shipment area, which is expected to grow 5 percent this year, according to IHS Inc., the global source of critical information and insight.

In addition to global currency issues that resulted in higher import prices for displays in most regions, slowing demand for information technology (IT) panels is driving down total unit shipments of large area TFT LCD displays. Combined year-over-year unit shipments for tablets, notebook PC and PC monitors will decline 12 percent. At the same time, TFT LCD TV panel unit shipments will increase by just 7 percent this year.

Similar to the unit-shipment trend, combined shipment area for displays used in PCs, notebooks and tablets is expected to decline 10 percent in 2015; however, year-over-year area shipments of TV panels is forecast to grow 9 percent this year. Increasing TV panel area shipment is leading to growth in the overall TFT LCD panel market, because TV displays comprise the vast majority (78 percent) of total panel area, according to the latest IHS Large Area Display Market Tracker

“Maintaining television panel production is the most important factor in maintaining the display industry’s fab utilization,” said Yoonsung Chung, director of large area display research for IHS Technology. “Chinese panel manufacturers have focused on increasing Gen 8 fabs for some time now. To consume this added capacity, TV panel makers must produce more panels, which means the industry could end up adding excess panels to inventory, leading to sharp TV panel price erosion in the second half of this year.”

Although the average selling price (ASP) for TV panels has already dropped dramatically, as inventory issues remain, prices will likely continue to decline in the coming year. “Panel price erosion will lower the cost of 55-inch-and-larger TVs, which could end up stimulating consumer demand for larger televisions,” Chung said.

What is true for double-blade razors is also true for solar cells: two work steps are more thorough than one. Stacking two solar cells one on top of the other, where top cell is semi-transparent, which efficiently converts large energy photons into electricity, while the bottom cell converts the remaining or transmitted low energy photons in an optimum manner. This allows a larger portion of the light energy to be converted to electricity. Up to now, the sophisticated technology needed for the procedure was mainly confined to the realm of Space or Concentrated Photovoltaics (CPV). These “tandem cells” grown on very expensive single crystal wafers are considered not attractive for mass production and low cost solar electricity. The research team working under Stephan Buecheler and Ayodhya N. Tiwari from the Laboratory for Thin Films and Photovoltaics at Empa-Swiss Federal Laboratories for Material Science and Technology has now succeeded in making tandem solar cells that are based on polycrystalline thin films, and the methods are suitable for large area low cost processing, Flexible plastic or metal foils could also be used as substrate in future. This marks a major milestone on the path to mass production of high-efficiency solar cells with low cost processes.

The secret behind the new process is that the researchers create the top solar cell perovskite film with a low-temperature procedure at just 50 degrees Celsius. This promises an energy-saving and cost-saving production stage for future manufacturing processes. The tandem solar cell yielded an efficiency rate of 20.5% when converting light to electricity. Already with this first attempt Empa researchers have emphasized that it has lots more potential to offer for better conversion of solar spectrum into electricity.

The semi-transparent perovskite solar cell absorbs UV, blue and yellow visible light. It allows red light and infrared radiation to pass through. Based on this principle, a double-layer "tandem solar cell" can be built with an efficiency that is much higher than single-layer solar cells. Credit: Empa

The semi-transparent perovskite solar cell absorbs UV, blue and yellow visible light. It allows red light and infrared radiation to pass through. Based on this principle, a double-layer “tandem solar cell” can be built with an efficiency that is much higher than single-layer solar cells. Credit: Empa

Molecular soccer balls as a substrate for the magic crystal

The key to this double success was the development of a 14.2% efficient semi-transparent solar cell, with 72% average transparency, made from methylammonium lead iodide deposited in the form of tiny perovskite crystals. The perovskite is grown on a thin interlayer made of the substance abbreviated as PCBM (phenyl-C61-butyric acid methyl ester) is used . Each PCBM molecule contains 61 carbon atoms interconnected in the shape of a soccer ball. The perovskite film is prepared by a combination of vapour deposition and spin coating onto this layer, which has tiny football like structure, followed by an annealing at a “lukewarm” temperature. This magic perovskite crystal absorbs blue and yellow spectrum of visible light and converts these into electricity. By contrast, red light and infrared radiation simply pass through the crystal. As a result, the researchers can attach a further solar cell underneath the semi-transparent perovskite cell in order to convert the remaining light into electricity.

Advantage of the double-layer cell: better use of the spectrum of sunlight

For the lower layer of the tandem solar cell, the Empa researchers use a CIGS cell (copper indium gallium diselenide), a technique that the team has been researching for years. Based on the CIGS cells, small-scale production is already under way for flexible solar cells. The advantage of tandem solar cells is that they exploit sunlight better. A solar cell can only convert radiation with an energy level higher than the bandgap of the semiconductor used. If the radiation energy is lower, no electricity is generated. If the radiation is higher in energy, the excess radiated energy is converted to heat and is lost. A double-layer solar cell like Empa’s perovskite CIGS cell can combine substances with differing bandgaps and thus efficiently convert a larger share of the incident solar energy to electricity.

More than 30% efficiency is possible

While very good single-layer polycrystalline solar cell may practically convert a maximum of 25% of the solar energy to electricity, tandem solar cells could increase this figure to beyond 30%. That’s according to Ayodhya Tiwari, head of the Thin Film and Photovoltaics laboratory. He does say, however, that a lot of research work is needed before that will be possible. “What we have achieved now is just the beginning. We will have to overcome many obstacles before reaching this ambitious goal. To do this, we will need lots of interdisciplinary experience and a large number of combinatorial experiments until we have found a semi-transparent high-performance cell together with the right base cell, and technologies for electrical interconnections of these solar cells.”

Stephan Bücheler, who coordinates the lab research in Tiwari’s team, reminds us that the race for efficiency in solar cell research is certainly not just an academic show. “When producing solar-powered electricity, only half of the costs are down to the solar module itself. The other half are incurred for the infrastructure: inverters, cables, carriers for the cells, engineering costs and installation. These ancillary costs are reduced when the solar cells become more efficient and can be built in smaller sizes as a result. This means that efficient solar cells are the key to low-cost renewable electricity.”

AKHAN Semiconductor, Inc., a developer of diamond semiconductor technology, celebrated the opening of its new global headquarters and production facility in Gurnee, Illinois, and announcing that its first commercial customer will take delivery of the first AKHAN diamond semiconductor based-technology products in Q1 2016.

The ceremony is being attended by Gurnee Mayor Kristina Kovarik, US Senator Dick Durbin, Illinois State Senator Melinda Bush, US Representatives Randy Hultgren and Robert Dold, or designees, and numerous other state, local, and international dignitaries.

AKHAN is actively hiring to staff the new facility, which is expected to employee 100 people in the next two years.

“As a native of Gurnee, I am proud to help spur a new era of innovation and semiconductor technology in my hometown, in the state of Illinois, right here in the Diamond Prairie,” said Adam Khan, CEO and Founder of AKHAN Semiconductor. “The opening of our new global headquarters and production facility is just the first step in our goal to transform the chip industry and to extend Moore’s Law. Our diamond semiconductor-based technology will enable a new generation of commercial, industrial and consumer products such as flexible and transparent displays that can be used in wearables and thinner consumer devices that last longer. On the commercial side, we expect to develop new products such as diamond windows for industrial, defense and aerospace applications.”

AKHAN’s technology is based on a new process that uses man-made diamond rather than silicon to produce new chip materials that are more cost effective, operate at higher temperatures, are thinner and require less power. It is a result of the marriage of two scientific breakthroughs: ability to use nanocrystalline diamond (NCD) films and a new doping process the makes it possible to use NCD as a semiconductor material.

The AKHAN facility is slated to begin production in Q1 2016 and will produce and deliver more than 1,000 diamond-based technology windows.

Silicon Labs has announced the acquisition of Telegesis, a supplier of wireless mesh networking modules based on Silicon Labs’ ZigBee technology. A privately held company founded in 1998 and based near London, Telegesis has established itself as a ZigBee expert with strong momentum in the smart energy market, providing ZigBee module solutions to many of the world’s top smart metering manufacturers.

In its official release, Silicon Labs said this strategic acquisition accelerates Silicon Labs’ roadmap for ZigBee and Thread-ready modules and enhances the company’s ability to support customer needs with comprehensive mesh networking solutions ranging from wireless system-on-chip (SoC) devices to plug-and-play modules backed by best-in-class 802.15.4 software stacks and development tools. Telegesis modules integrate the antenna and provide a pre-certified RF design that reduces certification costs, compliance efforts and time to market. Customers can migrate later from modules to cost-efficient SoC-based designs with minimal system redesign and full software reuse.

The market for ZigBee modules is large and growing. According to IHS Technology, 20 percent of all ZigBee PRO integrated circuits shipping today are used in modules, and ZigBee module shipments are expected to grow at a compounded rate of 24.6 percent between now and 2019.

Telegesis exclusively uses Silicon Labs’ ZigBee technology in its module products, which are deployed in smart meters, USB adapters and gateways for smart energy applications. Additional target applications include home automation, connected lighting, security and industrial automation. The modules come with Silicon Labs’ rigorously tested, field-proven EmberZNet PRO ZigBee protocol stack, which sets the bar for ZigBee stack reliability and has been deployed in more connected products than any other ZigBee PRO stack. Telegesis also offers comprehensive development and evaluation kits to help developers streamline their ZigBee-based applications.

“The addition of Telegesis’s successful module business strengthens Silicon Labs’ position as the market leader in mesh networking solutions for the Internet of Things,” said James Stansberry, senior vice president and general manager of Silicon Labs’ IoT products. “The combination of Telegesis modules, Silicon Labs mesh networking SoCs, best-in-class 802.15.4 software stacks and easy-to-use wireless development tools provides customers with a seamless migration path from modules to SoCs and from ZigBee to Thread-based networks.”

“The Telegesis team is truly excited to become an integral part of Silicon Labs,” said Ollie Smith, director of business development at Telegesis. “Together, our hardware and software engineering teams will drive innovation in wireless mesh networking while giving customers a flexible choice of module and SoC-based designs leveraging both ZigBee and Thread technology.”

Trillium US Inc, headquartered in Clackamas, OR, has announced the acquisition of the Oxford Instruments – Austin division, formerly known as Austin Scientific, effective November 23rd, 2015.  Focused on the helium compression based vacuum and temperature management and control sector, Oxford Instruments-Austin provides cryo pump, cold head and compressor service, a range of new cryogenic pumps, cold heads and helium compressors, as well as a full line of related spare parts and accessories.

“The Oxford Instruments-Austin acquisition serves a number of purposes for Trillium,” announced Graham Stone, President and CEO of Trillium. “We acquire a significant range of complementary products while strengthening our existing service capabilities, allowing us to further leverage our customer relationships, while also taking us into new markets,” he added.

Trillium currently operates a 12,000 SF facility in North Austin servicing primarily rough vacuum pumps and blowers, while the existing 23,000 SF Oxford Instruments-Austin facility is located in South Austin. “We have been very encouraged with the depth of engineering and the high quality level at Oxford Instruments-Austin . Bringing them into the Trillium family will allow us to achieve significant synergies and a larger critical mass by consolidating our TX operations to a single South Austin location,” said Glen Murray, Trillium’s General Manager and VP-Operations.

Trillium has significantly grown its offerings over the past five years from providing repair service and refurbished equipment to also include new products and spare parts. This transition began as part of the merger with Hamburg, NJ’s United Vacuum in 2011, and continues now with this most recent acquisition. “Adding Oxford Instruments-Austin’s portfolio to our existing product line further enhances Trillium’s value to the customer,” added Rob Breisch, Trillium’s VP-Sales and Marketing. “Our new cryogenic customers can now rely on us to provide a broader range of vacuum products and services, and our existing customer base can take advantage of Oxford Instruments-Austin’s world class support for cryo pumps and helium compressors,” he explained.

The business integration is already underway and Trillium plans to transact from South Austin starting November 23rd.  “Our immediate focus and number one priority is to ensure this transition is implemented quickly and seamlessly for our customers,” stated Graham Stone. He added, “Later phases in the process will include business system migration and consolidation of the facilities.”

Trillium expects to complete the full transition by June 2016.