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Texas Instruments Incorporated (TI) (NASDAQ: TXN) today announced the resignation of Brian Crutcher as president, CEO and a member of the TI board. The board has named Rich Templeton, the company’s chairman, to reassume the roles of president and CEO on an ongoing, indefinite basis, in addition to continuing as chairman. Templeton’s appointment is not temporary, and the board is not searching for a replacement.

Crutcher resigned due to violations of the company’s code of conduct.  The violations are related to personal behavior that is not consistent with our ethics and core values, but not related to company strategy, operations or financial reporting.

“For decades, our company’s core values and code of conduct have been foundational to how we operate and behave, and we have no tolerance for violations of our code of conduct,” said Mark Blinn, lead director of the TI Board. “Over the past 14 years, Rich has successfully led TI to become the company it is today, and we have great confidence in his values and ability to continue to lead this company forward.”

“I have tremendous pride in this company, and passion for continuing to make TI even stronger and better,” said Rich Templeton, TI chairman, president and CEO. “I remain dedicated to moving TI forward with an unwavering commitment to operate ethically and conduct ourselves professionally in everything we do.”

TI also reported second-quarter revenue of $4.02 billion, up 9 percent from the same quarter a year ago, and earnings per share of $1.40. EPS included a 3 cent discrete tax benefit not in the company’s original guidance. TI will provide full second-quarter results and third-quarter guidance in its earnings release and conference call on July 24.

Bruker Corporation today announced that it has acquired JPK Instruments AG (JPK), located in Berlin, Germany. In 2017, JPK Instruments had revenue of approximately 10 million Euro. JPK provides microscopy instrumentation for biomolecular and cellular imaging, as well as force measurements on single molecules, cells and tissues. JPK adds in-depth expertise in live-cell imaging, cellular mechanics, adhesion, and molecular force measurements, optical trapping, and biological stimulus-response characterization to Bruker. Financial details of the transaction were not disclosed.

Over the past five years, Bruker has developed a life science microscopy business that specializes in advanced technologies for neuroscience, live-cell imaging, and molecular imaging, which will be further augmented by JPK’s advanced technologies and applications. Bruker’s existing fluorescence microscopy techniques include performance-leading multiphoton microscopy, swept-field confocal microscopy, super-resolution microscopy, and single-plane illumination microscopy.

“We have been making a substantial investment in advanced technologies for life science imaging, and have built up a portfolio of fluorescence microscopy products that enable biologists in research areas that require deep, fast imaging at high resolution and at low phototoxicity,” commented Dr. Mark R. Munch, President of the Bruker NANO Group. “JPK’s products and applications capabilities nicely augment our current techniques.”

Anthony Finbow, Chairman at JPK, added: “The combination of these two businesses will enable further significant advances in life science imaging and drive the state of the industry. I am delighted that we have been able to achieve this result for JPK and for Bruker.”

“The business we have built aligns well with the new strategic direction of Bruker in life science microscopy, and we are very pleased to join them,” said Dr. Torsten Jaehnke, a JPK founder and CTO. “We plan to realize a number of valuable synergies going forward.”

JPK’s BioAFM and optical tweezer product families span a range of techniques, from imaging of biological samples to characterizing biomolecular and cellular force interactions. Its NanoWizard 4 BioScience AFM combines atomic force imaging with advanced optical fluorescence imaging and super-resolution microscopy for the ultimate combination in image resolution for molecules, membranes, and live cells. In addition, the ForceRobot enables single-molecule force spectroscopy for investigating receptor-ligand interactions or small molecule-protein binding interactions. The CellHesion product brings quantitative force measurement to live cells and tissues, enabling insights in cell-substrate and cell-cell interactions. Lastly, JPK’s NanoTracker optical tweezer provides an all-optical means for molecular and cellular force experiments.

JPK’s offerings and life science applications expertise are synergistic with Bruker’s existing portfolio of advanced fluorescence microscopy products. Bruker’s Ultima family of multiphoton microscopes features proprietary photoactivation and photostimulation capabilities and deeper penetration into biological tissues, enabling advanced brain slice and intra-vital studies. Bruker’s Opterra swept-field scanning confocal fluorescence microscope provides unique live-cell imaging capabilities with unsurpassed dynamic observation of fast cellular events. Additionally, the Vutara super-resolution single-molecule localization (SML) microscope utilizes patented Biplane Imaging technology to provide high-speed, 3D super resolution for multicolor live-cell imaging and visualization of chromosome conformation. With a leading series of single plane illumination products, such as the MuVi SPIM and InVi SPIM, Bruker offers unique performance and easiest-to-use light sheet instruments featuring the combination of low phototoxicity and high-speed imaging. The combined microscopy portfolio of the two companies will enable a unique range of correlative measurements for emerging life science applications.

By Pete Singer

The importance of data gathered and analysed in the subfab – the place where vacuum pumps, abatements systems and other supporting equipment operates – is growing. Increasingly, manufacturers are finding that these systems have a direct impact on yield, safety, cost-of-ownership and ultimately capacity and cycle time.

“The subfab is getting recognized evermore as a contributor to the overall fab effectiveness, particularly when the fab is looking to get last fractions of a percentage of performance efficiencies,” notes Alan Ifould, Global Market Sector Manager at Edwards.

There’s also keen interest in tying this data with process data from the fab, the MES (manufacturing execution software) system and ultimately the ERP (enterprise resource planning) system as part of today’s efforts to understand and control the entire data ecosystem.

Subfab data systems provide a volume of data related not only to vacuum and abatement equipment, but also upstream, to the foreline, gate valve and chamber. Of special interest is the monitoring of vacuum faults, which can negatively impact quality, cost and safety. “A vacuum fault is anything that results in a loss of a degradation in vacuum,” said Ifould.

Ideally, faults – and the overall quality of the vacuum system — are proactively managed. Potential faults are detected days or even weeks before they occur and addressed during regularly scheduled tool maintenance, for example. “We’re finding that our ability to detect vacuum faults in the wider vacuum system comes very much to the fore,” Ifould said.

Data seen at the pump or abatement can help determine the size and location of vacuum system leaks. Algorithms based around vacuum science and thermodynamics can lead engineers to problematic leaks that, over time, can have a significant impact on yield.

Often, the first reaction to a loss in chamber pressure is to blame the vaccum pump, Ifould said. Vacuum pumps can be swapped out in about 4 hours, but if the process tool goes down while in operation, it could be in excess of 48 hours to get everything back up and running. Even then, it might be something other than the pump that caused the initial problem, such as a leak in a gate valve or in the foreline. It’s essential to accurately diagnose the problem(s) at the onset, but that can be a challenge: “You only need a small leak in a gate valve, and you immediately have problems with maintaining the base pressure in the chamber. The pump may become overloaded because of the additional gas load caused by leaks,” he said.

Edwards has developed a verity of new data collection and analysis strategies aimed at improving such decision making. The SMA (Site Management Application) is latest addition to data analytics portfolio, focused on subfab. As shown in Figure, SMA is designed to provide insight into maintenance activities, equipment performance and fault resolution. It is implemented in parallel with the company’s VTPS (Vacuum Technique Production System), which drives standard work and behaviors based on LEAN principles and best known methods.

Edwards is also working on what it calls “sensorization” where, for example, the use of vibration analytics can detect anomalies otherwise missed by traditional monitoring techniques.

Ifould said the SMA and sensorization helps improve the stability of fab operations by bringing veracity to the data. “It’s one thing to have a volume of data, but the data itself is of little value unless it’s of good quality,” he said. “When we’re looking at equipment operations and the way you have operators involved, being able to bring discipline to the behaviors of those operators to the task that they perform brings discipline to the data and improves the veracity of the data,” he said.

He said Edwards has been using this approach to “great effect” over the last year. “We can help our customers see where some of their maintenance practices need to be improved to eliminate some of the sources of error that cause some of those vacuum faults,” he said.

More recently, Edwards is looking to move beyond a simple predictive maintenance model (PdM) to a model that include quality (PdMQ). The model includesnot only the condition of the subfab equipment, but of the quality of the vacuum it provides, and therefore the process it supports. “We’re not just considering the condition of the subfab equipment and being able to predict when that may fail, but considering the quality of the vacuum that system actually provides.”

Harnessing data from all parts of the fab ecosystem is essential, Ifould notes, but has its challenges, especially when it comes to IP. “In an ideal world, we would like to receive contextualized data which allows us to relate what’s happening in the vacuum pump into the process itself. That becomes challenging because of the IP sensitivity,” he said.

Site Management Application, the latest addition to Edwards’ data analytics portfolio, is designed to provide insight into maintenance activities, equipment performance and fault resolution.

Market shares of semiconductor equipment manufacturers shifted significantly in Q1 2018 as Applied Materials, the top supplier dropped, according to the report “Global Semiconductor Equipment: Markets, Market Shares, Market Forecasts,” recently published by The Information Network, a New Tripoli-based market research company.

The chart below shows shares for the first quarter (Q1) of calendar year 2017 and 2018. Market shares are for equipment only, excluding service and spare parts, and have been converted for revenues of foreign companies to U.S. dollars on a quarterly exchange rate.

Applied Materials lost significant market share YoY, from 18.4% of the $13.1 billion Q1 2017 market to 17.7% of the $17.0 billion Q1 2018 market. This drop follows a 1.8 share-point loss by Applied Materials for CY 2017 compared to 2016. The company competes with Lam Research and TEL in the deposition and etch market, and both gained share at the expense of Applied Materials.

At the other end of the spectrum, smaller semiconductor companies making up the “other” category lost 2.4 share points as a whole.

Much of the equipment revenue growth was attributed to strong growth in the DRAM and NAND sectors, as equipment was installed in memory manufacturers Intel, Micron Technology, Samsung Electronics, SK Hynix, Toshiba, and Western Digital. The memory sector, which grew grown 61.5% in 2017, is forecast to add another 28.5% in 2018 according to industry consortium WSTS (World Semiconductor Trade Statistics).

TEL recorded growth of 120.3% YoY in Korea, much of it on NAND and DRAM sales to Samsung Electronics and SK Hynix, and 69.5% YoY in Japan, much of it on NAND sales to Toshiba at its Fab 6 in Kitakami, Japan. Lam Research gained 42.2% and 70.5% YoY, respectively, in Korea and Japan.

Following the strong growth in the semiconductor equipment market, The Information Network projects another 11.5% growth in 2018 for semiconductor equipment.

By Paula Doe

Chip testing is becoming smarter and more complex, creating growing requirements to stream data in real time and ensure it is ready to use for analysis, regardless of the vendor source.

Adaptive testing using machine learning to predict die performance in a downstream test can reduce the number of cycles by as much as 40 per cent without compromising test performance, notes Dan Sebban, VP of data analysis, OptimalPlus, who’ll speak on machine learning challenges at SEMICON West’s Test Vision 2020 program. “As devices and their test requirements grow in complexity, the motivation for automating adaptive test greatly increases,” he states, adding that characteristics such as die location on the wafer, defects on neighboring die, condition of the tester, and test values near the specification limits can help predict which die are likely to be good.

“The big issue we see is that while everyone likes the idea of machine learning, it remains a black box model, with little visibility into why it makes the decisions it does,” adds Sebban. In addition, a suitable infrastructure to run, deploy and assess a machine learning model in real time is required. “There is still some hesitation to adopt machine learning. It’s a big change of mindset. While building the confidence to use machine learning will take time and experience, using the technology to automate big data analysis with the relevant infrastructure may be our best alternative to reduce test cost.”

Systems test and parts-per-billion quality become the rule

Systems test will continue to become more prominent and more complex as chips and packages shrink, affirms Stacy Ajouri, Texas Instruments system integration engineer and Test Vision 2020 event chair. “Even IC makers now need to start doing more systems test.” And as more ICs are used in automotive applications, the distinction between consumer and automotive requirements is blurring, driving demand in other markets for higher precision test with parts-per-billion defectivity requirements.

“Intelligent test gets increasingly challenging as devices become more complex and as testing moves from distinguishing good from bad devices to figuring out how to repair and trim marginal devices to make them good,” adds Derek Floyd, Advantest director of business development, this year’s program chair.

“We’re highlighting efforts to create the infrastructure the industry needs to manage big data for machine learning with test platforms from different vendors,” says Ajouri, citing work on new standards for streaming data from the testers and labeling critical steps in consistent language to simplify the use of data from different platforms in real time. “I have 10 platforms from multiple vendors, and I need them to mean exactly the same thing by ‘lot’ so I don’t have to sort it out before I can use the data,” she says.

Are devices becoming too complicated to test at the required price point?

Can testing be economical with up to a million die per wafer, 50 data points per die, a requirement for parts-per-billion accuracy, and the need to identify parts that test good now but that might fail in the future? Organizers of the event invite chipmakers and test suppliers to debate the issue. “The speed of innovation in the semiconductor industry challenges test to keep pace,” notes Floyd. “The product we’re testing is always ahead of the product we have to test it with.”

The two-day event features sessions on automotive test; big data and machine learning for adaptive test; handling and interface issues such as over-the-air testing;  and a general session covering memory and RF test.

SEMICON West next week will host a White House-led discussion of the anticipated national leadership strategy for semiconductors, a multi-agency initiative led by top U.S. government national security and economic organizations.

On Wednesday, July 11, a panel of U.S. officials representing agencies involved in leading the strategy will address federal research and development (R&D), investment and acquisition priorities aimed at ensuring the U.S. remains the global leader in the semiconductor industry.

As global economic trends and technologies such as artificial intelligence evolve, and foreign governments increasingly lure microelectronics manufacturing investments overseas, the U.S. strategy for manufacturing advanced semiconductors and driving research and development (R&D) in technology innovation has become an economic priority.

The White House selected SEMICON West, organized by SEMI, as the site for the discussion and this urgent call to action because of the event’s central role in bringing together critical industries across the global electronics supply chain. The multi-agency panel will outline activities and new policies under development to ensure U.S. strategic leadership in microelectronics, including focused investment in innovations key to the next generation of devices for commercial and government use. The initiative also includes public-private partnerships to accelerate the capabilities of advanced semiconductors for critical applications such as artificial intelligence (AI), cyber, secure communications, the internet of things (IoT) and big data analytics.

PANEL:
National Strategy for Semiconductor and Microelectronic Innovation
TIME AND DATE:
10:30 to 11:30 a.m., Wednesday, July 11
LOCATION:
Yerba Buena Theater, 700 Howard St., San Francisco
MODERATOR:
Dr. Lloyd Whitman, Principal Assistant Director, Physical Sciences and Engineering, White House Office of Science and Technology Policy
PANELISTS:
Dr. Sankar Basu, Program Director, Computer and Information Science and Engineering, National Science Foundation
Dr. Eric W. Forsythe, Flexible Electronics Team Leader, U.S. Army Research Laboratory
Dr. Jeremy Muldavin, Deputy Director of Defense Software & Microelectronics Activities, Office of the Deputy Assistant Secretary of Defense for Systems Engineering
Dr. Robinson Pino, Acting Research Division Director, Advanced Scientific Computing Research, Office of Science, Department of Energy

 

SEMICON West is organized by SEMI Americas to connect more than 2,000 member companies and 1.3 million professionals worldwide to advance the technology and business of electronics manufacturing. SEMICON West is celebrating its 47th year as the flagship event for the semiconductor industry. Find more at www.semiconwest.org.

The SiC power market is now on the road, asserts Yole Développement (Yole). Therefore, since 2017, the market research and strategy consulting company identified more than 20 strategic announcements, showing the dynamism of this market and attractiveness of the technology. Rohm, Bombardier, Cree, SDK, STMicroelectronics, Infineon Technologies, Littelfuse, Ascatron and more are part of the powerful ecosystem, presenting innovative products and revealing key partnerships and/or M&A .

Today, SiC transistors are clearly being adopted, penetrating smoothly into different applications. Yole’s analysts forecast a US$1.4 billion SiC power semiconductor market by 2023. According to the Power & Wireless team at Yole, this market is showing a 29% CAGR between 2017 and 2023.
Power SiC report, 2018 edition presents Yole’s deep understanding of SiC penetration in different applications including xEV, xEV charging infrastructure, PFC/power supply, PV, UPS, motor drives, wind and rail. In addition, it highlights the state-of-the-art SiC-based devices, modules, and power stacks. Yole’s analysts also describe the SiC power industrial landscape from materials to systems, and analyze of SiC power market dynamics. This report proposes a detailed quantification of the SiC power device market until 2023, in value and volume.

SiC adoption is accelerating: is the supply chain ready? Yole’s analysts reveal today their vision of the SiC industry.

SiC market is still being driven by diodes used in PFC and PV applications. However Yole expects that in five years from now the main SiC device market driver will be transistors, with an impressive 50% CAGR for 2017-2023.

This adoption is partially thanks to the improvement of the transistor performance and reliability compared to the first generation of products, which gives confidence to customers for implementation.

Another key trend revealed by Yole’s analysts is the SiC adoption by automotive players, over the next 5-10 years. “Its implementation rate differs depending on where SiC is being used,” comments Dr. Hong Lin, Technology and Market Analyst, Compound Semiconductors at Yole. “That could be in the main inverter, in OBC or in the DC/DC converter. By 2018, more than 20 automotive companies are already using SiC SBDs or SiC MOSFET transistors for OBC, which will lead to 44% CAGR through to 2023.”

Yole expects SiC adoption in the main inverter by some pioneers, with an inspiring 108% market CAGR for 2017-2023. This will be possible because nearly all carmakers have projects to implement SiC in the main inverter in coming years. In particular, Chinese automotive players are strongly considering the adoption of SiC.

The recent SiC module developed by STMicroelectronics for Tesla and its Model 3 is a good example of this early adoption. The SiC-based inverter, analyzed by System Plus Consulting, Yole’s sister company is composed of 24 1-in-1 power modules. Each module contains two SiC MOSFETs with an innovative die attach solution and connected directly on the terminals with copper clips and thermally dissipated by copper baseplates. The thermal dissipation of the modules is performed thanks to a specifically designed pin-fin heatsink.

“SiC MOSFET is manufactured with the latest STMicroelectronics technology design,” explains Dr. Elena Barbarini, Head of Department Devices at System Plus Consulting. “This technical choice allows reduction of conduction losses and switching losses”. STMicroelectronics is strongly involved in the development of SiC-based modules for the automotive industry. During its recent Capital Markets Day, the leading player details its activities in this field (Source: Automotive & Discrete Group presentation – May 2018). STMicroelectronics is also commited in the development of innovative packaging solutions. . System Plus Consulting proposes today a complete teardown analysis including a detailed estimation of the production cost of the module and its package.

PV has also caught the attention of Yole’s analysts during recent months. China claimed almost the half of the world’s installations in the last year. However due to new governmental regulations, Yole sees a slow down of the PV market in short term and has lowered its expectation of SiC penetration for the segment.

In general, system manufacturers are interested in implementing cost effective systems which are reliable, without any technology choice, either silicon or SiC. “Today, even if it’s certified that SiC performs better than silicon, system manufacturers still get questions about long term reliability and the total cost of the SiC inverter”, comments Ana Villamor, Technology & Market Analyst, Power Electronics & Compound Semiconductors at Yole.

Yole and System Plus Consulting teams will attend SEMICON Europa 2018 (Munich, Germany – November 13-16). During the leading trade show, Dr. Milan Rosina, Senior Technology & Market Analyst, Power Electronics & Batteries at Yole proposes a dedicated WBG presentation on November 15 at 2:30 PM.

SiC and GaN devices have demonstrated their large potential for power electronic applications. During the presentation “GaN and SiC power device: market overview” taken place during the Power Electronics Session, Dr. Rosina proposes an overview of the market, technology and the industrial supply chain. More information available on i-micronews.com, Conferences & Trade Shows section.

TowerJazz, the global specialty foundry, today announced details on its 13th annual Technical Global Symposium (TGS) being held in China, Japan, and the United States. This year, TowerJazz TGS will focus on the Company’s leading analog technology offerings, advanced manufacturing solutions and commitment to customer partnerships. All TGS events will commence with a keynote from TowerJazz CEO, Mr. Russell Ellwanger focusing on the Company’s performance, business strategy and industry leadership through alignment with customer roadmaps, innovative and superior technology, and worldwide manufacturing capabilities.

During TGS, speakers will discuss market directions and the latest TowerJazz plans, developments and activities for strategic growth in its specialty process technologies such as Radio Frequency (RF) & High Performance Analog (HPA), power management, and CMOS image sensors (CIS), as well as its process transfer offering (TOPS) for the rising markets of automotive, sensors, the IoT, and 5G, among others. In addition, TowerJazz will present the latest design enablement tools and solutions jointly developed with its EDA partners as well as the Company’s expanded manufacturing capacity and multi-sourcing capabilities.

The global TGS events facilitate customer and partner interaction with TowerJazz team members and industry executives to exchange information on the latest unique and advanced solutions for next-generation analog ICs. TowerJazz focuses on strong roadmap alignment and long-term partnerships with its customers to meet their current and future needs with the most innovative process platforms, addressing the requirements of the fastest growing markets.

As the leading analog pure play foundry, TowerJazz continues to be committed and passionate toward creating value for its customers. The Company offers the most advanced analog technology and best-in-class design enablement while providing global capacity assurance and flexibility to enable customers with competitive advantage and fast time to market.

This year, TowerJazz TGS events will be hosted in the following locations:

Sponsors at TowerJazz TGS events include the industry’s leading EDA vendors and tool providers who will share the latest design capabilities offered in collaboration with TowerJazz: Cadence, HES, Integra Tech, Keysight Technologies, Magwel, Mentor, PacTech, Photronics, Presto, Silvaco, Synkom and Synopsis.

For more information about TowerJazz TGS and registration please visit:
http://www.towerjazz.com/events.html#tgs

Micron Technology, Inc. (Nasdaq:MU) today announced volume production on its 8Gb GDDR6 memory. Built on experience and execution for several generations of GDDR memory, GDDR6 – Micron’s fastest and most powerful graphics memory designed in Micron’s Munich Development Center – is optimized for a variety of applications that require high performance memory, including artificial intelligence (AI), networking, automotive and graphics processing units (GPUs). Additionally, Micron has worked with core ecosystem partners to ramp GDDR6 documentation and interoperability, enabling faster time to market for designs.

“Micron is a pioneer in developing advanced high bandwidth memory solutions and continues that leadership with GDDR6. Micron demonstrated this leadership by recently achieving throughput up to 20 Gb/s on our GDDR6 solutions,” said Andreas Schlapka, director, Compute Networking Business Unit, Micron. “In addition to performance increases, Micron has developed a deep partner ecosystem to enable rapid creation of GDDR6 designs, enabling faster time to market for customers looking to leverage this powerful new memory technology.”

The need for high performance GDDR6 memory has grown as end-users demand advanced applications. GDDR6 enables advanced performance with lower power consumption in a number of segments including:

  • Artificial Intelligence – Artificial intelligence, machine learning, deep learning are memory intensive applications that require more bandwidth from memory solutions. GDDR6 delivers the higher bandwidth required to accelerate AI in applications like computer vision, autonomous driving and the many other applications that require this higher bandwidth.
  • Graphics – Enabling significant performance improvements for today’s top GPUs, GDDR6 delivers enhanced graphic memory speeds to enable higher application bandwidth. Micron GDDR6 will be a core enabling technology of advanced GPU applications, including acceleration, 4K video and improved rendering, VR/AR and crypto mining applications.
  • Networking – Advanced networking technologies require access to high speed/high bandwidth memory. GDDR6-powered smart Network Interface Cards (NIC) enable significant improvements in network bandwidth. Additionally, high bandwidth RAID controllers featuring GDDR6 memory deliver dramatic enhancements to data access and protection.
  • Automotive – As auto manufacturers push for autonomous vehicles, high performance memory is required to process the vast amounts of real-time data required to make this technology a reality. Micron GDDR6 delivers 448 GB/s auto qualified memory solutions, that deliver more than double the bandwidth of LPDDR5 automotive memory solutions.

“As demand for advanced automotive applications such as ADAS and other autonomous driving solutions grows, the need for high bandwidth memory in automotive will grow as well. Advanced high bandwidth GDDR6 memory solutions are a key enabling technology for autonomous vehicles and will be an important tool for the automotive industry as they develop next generation transportation initiatives,” said Kris Baxter, vice president, Marketing, Micron’s Embedded Business Unit.

Targeting up to 64GB/s in one package, GDDR6 brings a significant improvement over the fastest available GDDR5. This unprecedented level of single-chip performance, using proven, industry-standard BGA packaging provides designers a powerful, cost-efficient and low-risk solution using the most scalable, high-speed discrete memory available to the market.

In order to deliver this leading edge high bandwidth memory technology to customers, Micron is working directly with ecosystem partners in order to enable learning on both pre-silicon verification as well as validation. Prior to mass production of GDDR6 memory, Micron shipped early validation silicon to our ecosystem partners to accelerate engineering efforts behind validating intellectual property and build robust models and toolsets in the ecosystem and deliver board layout validation. This ensures that engineers are able to implement GDDR6 in designs at a faster rate and bring bandwidth intensive applications to the marketplace. These ecosystem partners include Rambus and more.

“With nearly 30 years’ experience in implementing designs for high-speed interfaces, Rambus is the first IP provider to launch a comprehensive GDDR6 PHY solution for next-generation AI, ADAS, networking and graphics applications and continues to be at the leading edge of implementing industry standards. We are proud to work with Micron and other ecosystem partners to help customers accelerate time to market for GDDR6 designs and deliver the most advanced solutions based on GDDR6 memory,” said Frank Ferro, senior director of product marketing, Rambus.

Micron GDDR6 memory solutions will be on display in booth B-1340 at ISC 2018, June 24-28, in Frankfurt, Germany. For more information, visit www.micron.com.

According to a recent report published by Allied Market Research, titled, Global Organic CMOS Image Sensor Market by Image Processing, Array Type, Industry Vertical and Application: Global Opportunity Analysis and Industry Forecast, 2020-2025, the global organic CMOS image sensor market is expected to value at $696.0 million in 2020, and is projected to reach $1,750.0 million by 2025, registering a CAGR of 20.9% from 2021 to 2025.

At present, North America dominates the market, followed by Europe. In 2020, U.S dominated the North America market and rest of Europe led the overall market in Europe. However, in North America, the U.S. currently dominates the market.

The high photoelectric conversion property, better low-light performance and richer colors & textures drive of the organic CMOS image sensor make way for the growth of the market. In addition, introduction of technologies such as 8K resolution and global shutter technology also contribute to the market growth. However, excessive generation of heat in the organic sensor technology hampers this stated growth.

Key Findings of the Organic CMOS Image Sensor Market:

  • The linear image sensors segment generated the highest revenue in the global organic CMOS image sensor market in 2020.
  • In 2020, the 2D Sensors segment was the highest revenue contributor in the image processing segment.
  • Asia Pacific is anticipated to exhibit the highest CAGR during the forecast period.
  • In 2020, North America contributed the highest market share, followed by Europe, Asia Pacific and LAMEA.

The key players profiled in the report include are Fujifilm Corporation, Panasonic Corporation, Sony Corporation, Samsung Electronics, Siemens AG, NikkoIA SAS, Xenics NV, AMS AG, Canon, and OmniVision Technologies, Inc.