Category Archives: MEMS

Year End Wow!


January 24, 2018

By Walt Custer, Custer Consulting Group

Strong year-end 2017 electronic equipment sales

2017 ended on a high note from an end market perspective thanks to:

  • Geographically broad economic strength and new products
  • Record high December electronic equipment production and shipments in China/Taiwan
  • Peak electronic equipment production in the Eurozone in November
  • A 4Q upturn in U.S. bookings and shipments of electronic equipment

Custer1-World-Electronic-Equipment-Monthly-Shipments

Based upon preliminary data, mobile phones including the Apple iPhone X were major contributors to the fourth-quarter 2017 strength in Asia/Pacific. Foxconn registered all-time record sales in December.

By comparison, personal computer sales were flat when adjusted for normal seasonality.

Early information indicates that December global equipment revenues were up almost 24 percent over December 2016 and up 3 percent sequentially over November 2017.

Resilient semiconductor supply chain

Semiconductors and SEMI equipment have a strong growth in this current business cycle (Chart 2), mainly due to strong memory demand and price increases for chips, and also robust capital equipment spending to increase memory chip capacity.

Custer2-World-Semiconductor-SEMI-Equipement-Shipments

 

By November this sales growth appeared to be plateauing (but at record levels).

On a 3/12 basis (Chart 3) world growth was:

Semiconductors +21.5% November
SEMI equipment +28.4% November
Taiwan Chip Foundries +6.1% December
Electronic Equipment +4.9% September

Custer3-Supply-Chain-Dynamics
Despite a likely moderation of the current SEMI equipment and chip growth rates, this current business cycle has been robust and prolonged. End market electronic equipment demand remains strong and new volume markets are emerging. However SEMI equipment and semiconductor sales are much more volatile than electronic equipment, so the current landscape could change quickly.

Looking forward

The global PMI is an excellent short-term leading indicator. It was at an all-time record high in December, pointing to an unseasonably strong first quarter of 2018. Keep watching the business cycles for any signs of abrupt change. Currently we are on a high plateau but conditions could change quickly.

Custer4-Purchasing-Managers-Index

Originally published on the SEMI blog.

Technavio market research analysts forecast the global reset IC market to grow at a CAGR of close to 12% during the forecast period, according to their latest report.

The report further segments the global reset IC market by end-user (consumer electronics, telecommunication, automotive, industrial, and healthcare), by type (1-5 V, 5-12 V, and above 10 V), and by geography (the Americas, APAC, and EMEA).

Technavio analysts highlight the following three market drivers that are contributing to the growth of the global reset IC market:

  • Growth of smart grid technology
  • Increasing need for external brownout protection
  • Growth of IoT

Growth of smart grid technology

Due to their reliability and real-time information, smart grids have become an important trend in the energy industry. A smart grid is an electricity supply network integrated with digital communications technology to detect and react to local changes in the consumption of electricity and it is equipped with computational intelligence and network capabilities.

According to a senior analyst at Technavio for embedded systems research, “Smart grids are developed to improved operations and the maintenance of electric grids by allowing smooth exchange of data between various components. Transmission lines, generators, transformers, smart meters, smart appliances, and energy-efficient devices are components of a smart grid.”

Increasing need for external brownout protection

Restriction or reduction in the availability of electrical power in an area or locality is known as brownout. Voltage is limited or regulated in a brownout, unlike a blackout where the supply of voltage is completely removed for a period of time. Voltage overload on power grid and aging electrical system are some of the causes of brownouts. A reset IC sometimes integrates a brownout detector (BOD). It helps in preventing a reset if the voltage drops unexpectedly for a short duration of time.

Growth of IoT

The significant growth of IoT proved to be a major driver for the global reset IC market. IOT is a system of interrelated computing devices, machines, objects, and people, which are provided with unique identifiers. Without the need for any human-to-human or human-to-computer interaction, IoT allows the transfer of data over a network. IoT is also driving the demand for connected devices, which has significantly increased the bandwidth requirements. Vendors in the market are working together to satisfy the need for connecting several products, including gateways, home appliances, entertainment systems for smart homes, by a common networking standard that provides interoperability with a wide range of smart devices.

IoT will drive the need for enabler technologies which will have an impact on semiconductor foundries. An enabler technology can be classified as an invention, product, or technology which can provide a radical change in a user or an application. IoT shows great potential in several applications, which will drive the market.

Illinois researchers have demonstrated that sound waves can be used to produce ultraminiature optical diodes that are tiny enough to fit onto a computer chip. These devices, called optical isolators, may help solve major data capacity and system size challenges for photonic integrated circuits, the light-based equivalent of electronic circuits, which are used for computing and communications.

Isolators are nonreciprocal or “one-way” devices similar to electronic diodes. They protect laser sources from back reflections and are necessary for routing light signals around optical networks. Today, the dominant technology for producing such nonreciprocal devices requires materials that change their optical properties in response to magnetic fields, the researchers said.

“There are several problems with using magnetically responsive materials to achieve the one-way flow of light in a photonic chip,” said mechanical science and engineering professor and co-author of the study Gaurav Bahl. “First, industry simply does not have good capability to place compact magnets on a chip. But more importantly, the necessary materials are not yet available in photonics foundries. That is why industry desperately needs a better approach that uses only conventional materials and avoids magnetic fields altogether.”

In a study published in the journal Nature Photonics, the researchers explain how they use the minuscule coupling between light and sound to provide a unique solution that enables nonreciprocal devices with nearly any photonic material.

However, the physical size of the device and the availability of materials are not the only problems with the current state of the art, the researchers said.

“Laboratory attempts at producing compact magnetic optical isolators have always been plagued by large optical loss,” said graduate student and lead author Benjamin Sohn. “The photonics industry cannot afford this material-related loss and also needs a solution that provides enough bandwidth to be comparable to the traditional magnetic technique. Until now, there has been no magnetless approach that is competitive.”

The new device is only 200 by 100 microns in size – about 10,000 times smaller than a centimeter squared – and made of aluminum nitride, a transparent material that transmits light and is compatible with photonics foundries. “Sound waves are produced in a way similar to a piezoelectric speaker, using tiny electrodes written directly onto the aluminum nitride with an electron beam. It is these sound waves that compel light within the device to travel only in one direction. This is the first time that a magnetless isolator has surpassed gigahertz bandwidth,” Sohn said.

The researchers are looking for ways to increase bandwidth or data capacity of these isolators and are confident that they can overcome this hurdle. Once perfected, they envision transformative applications in photonic communication systems, gyroscopes, GPS systems, atomic timekeeping and data centers.

“Data centers handle enormous amounts of internet data traffic and consume large amounts of power for networking and for keeping the servers cool,” Bahl said. “Light-based communication is desirable because it produces much less heat, meaning that much less energy can be spent on server cooling while transmitting a lot more data per second.”

Aside from the technological potential, the researchers can’t help but be mesmerized by the fundamental science behind this advancement.

“In everyday life, we don’t see the interactions of light with sound,” Bahl said. “Light can pass through a transparent pane of glass without doing anything strange. Our field of research has found that light and sound do, in fact, interact in a very subtle way. If you apply the right engineering principles, you can shake a transparent material in just the right way to enhance these effects and solve this major scientific challenge. It seems almost magical.”

The historic flood of merger and acquisition agreements that swept through the semiconductor industry in 2015 and 2016 slowed significantly in 2017, but the total value of M&A deals reached in the year was still more than twice the annual average in the first half of this decade, according to IC Insights’ new 2018 McClean Report, which becomes available this month.  Subscribers to The McClean Report can attend one of the upcoming half-day seminars (January 23 in Scottsdale, AZ; January 25 in Sunnyvale, CA; and January 30 in Boston, MA) that discuss the highlights of the report free of charge.

In 2017, about two dozen acquisition agreements were reached for semiconductor companies, business units, product lines, and related assets with a combined value of $27.7 billion compared to the record-high $107.3 billion set in 2015 and the $99.8 billion total in 2016 (Figure 1).  Prior to the explosion of semiconductor acquisitions that erupted several years ago, M&A agreements in the chip industry had a total annual average value of about $12.6 billion between 2010 and 2015.

Figure 1

Figure 1

Two large acquisition agreements accounted for 87% of the M&A total in 2017, and without them, the year would have been subpar in terms of the typical annual value of announced transactions.  The falloff in the value of semiconductor acquisition agreements in 2017 suggests that the feverish pace of M&A deals is finally cooling off.  M&A mania erupted in 2015 when semiconductor acquisitions accelerated because a growing number of companies began buying other chip businesses to offset slow growth rates in major end-use applications (such as smartphones, PCs, and tablets) and to expand their reach into huge new market opportunities, like the Internet of Things (IoT), wearable systems, and highly “intelligent” embedded electronics, including the growing amount of automated driver-assist capabilities in new cars and fully autonomous vehicles in the not-so-distant future.

With the number of acquisition targets shrinking and the task of merging operations together growing, industry consolidation through M&A transactions decelerated in 2017.  Regulatory reviews of planned mergers by government agencies in Europe, the U.S., and China have also slowed the pace of large semiconductor acquisitions.

One of the big differences between semiconductor M&A in 2017 and the two prior years was that far fewer megadeals were announced.  In 2017, only two acquisition agreements exceeded $1 billion in value (the $18 billion deal for Toshiba’s memory business and Marvell’s planned $6 billion purchase of Cavium).  Ten semiconductor acquisition agreements in 2015 exceeded $1 billion and seven in 2016 were valued over $1 billion.  The two large acquisition agreements in 2017 pushed the average value of semiconductor M&A pacts to $1.3 billion.  Without those megadeals, the average would have been just $185 million last year. The average value of 22 semiconductor acquisition agreements struck in 2015 was $4.9 billion.  In 2016, the average for 29 M&A agreements was $3.4 billion, based on data compiled by IC Insights.

Engineers worldwide have been developing alternative ways to provide greater memory storage capacity on even smaller computer chips. Previous research into two-dimensional atomic sheets for memory storage has failed to uncover their potential — until now.

A team of electrical engineers at The University of Texas at Austin, in collaboration with Peking University scientists, has developed the thinnest memory storage device with dense memory capacity, paving the way for faster, smaller and smarter computer chips for everything from consumer electronics to big data to brain-inspired computing.

Illustration of a voltage-induced memory effect in monolayer nanomaterials, which layer to create "atomristors," the thinnest memory storage device that could lead to faster, smaller and smarter computer chips. Credit: Cockrell School of Engineering, The University of Texas at Austin

Illustration of a voltage-induced memory effect in monolayer nanomaterials, which layer to create “atomristors,” the thinnest memory storage device that could lead to faster, smaller and smarter computer chips. Credit: Cockrell School of Engineering, The University of Texas at Austin

“For a long time, the consensus was that it wasn’t possible to make memory devices from materials that were only one atomic layer thick,” said Deji Akinwande, associate professor in the Cockrell School of Engineering’s Department of Electrical and Computer Engineering. “With our new ‘atomristors,’ we have shown it is indeed possible.”

Made from 2-D nanomaterials, the “atomristors” — a term Akinwande coined — improve upon memristors, an emerging memory storage technology with lower memory scalability. He and his team published their findings in the January issue of Nano Letters.

“Atomristors will allow for the advancement of Moore’s Law at the system level by enabling the 3-D integration of nanoscale memory with nanoscale transistors on the same chip for advanced computing systems,” Akinwande said.

Memory storage and transistors have, to date, always been separate components on a microchip, but atomristors combine both functions on a single, more efficient computer system. By using metallic atomic sheets (graphene) as electrodes and semiconducting atomic sheets (molybdenum sulfide) as the active layer, the entire memory cell is a sandwich about 1.5 nanometers thick, which makes it possible to densely pack atomristors layer by layer in a plane. This is a substantial advantage over conventional flash memory, which occupies far larger space. In addition, the thinness allows for faster and more efficient electric current flow.

Given their size, capacity and integration flexibility, atomristors can be packed together to make advanced 3-D chips that are crucial to the successful development of brain-inspired computing. One of the greatest challenges in this burgeoning field of engineering is how to make a memory architecture with 3-D connections akin to those found in the human brain.

“The sheer density of memory storage that can be made possible by layering these synthetic atomic sheets onto each other, coupled with integrated transistor design, means we can potentially make computers that learn and remember the same way our brains do,” Akinwande said.

The research team also discovered another unique application for the technology. In existing ubiquitous devices such as smartphones and tablets, radio frequency switches are used to connect incoming signals from the antenna to one of the many wireless communication bands in order for different parts of a device to communicate and cooperate with one another. This activity can significantly affect a smartphone’s battery life.

The atomristors are the smallest radio frequency memory switches to be demonstrated with no DC battery consumption, which can ultimately lead to longer battery life.

“Overall, we feel that this discovery has real commercialization value as it won’t disrupt existing technologies,” Akinwande said. “Rather, it has been designed to complement and integrate with the silicon chips already in use in modern tech devices.”

2018FLEX, the Flexible Hybrid Electronics (FHE) Conference and Exhibition, will bring together more than 600 experts from around the world for business-critical insights and the latest technology in both flexible electronics and MEMS and sensors. 2018FLEX – February 13-15 in Monterey, California – will spotlight FHE innovation drivers in smart medtech, smart automotive, smart manufacturing, Internet of Things (IoT) and consumer electronics. The event, hosted by SEMI FlexTech, will feature more than 100 market and technical presentations, 60 exhibits, short courses and opportunities to connect with industry visionaries.

This year 2018FLEX will co-locate with the MEMS & Sensors Technical Congress (MSTC). February 13-14, MSTC will highlight leading-edge MEMS and sensors system-level solutions, technology and applications. Click here to register for both events.

The flexible and printed electronics markets are expected to reach $20 billion by 2022, with a compound annual growth rate (CAGR) of 21.5 percent from 2016 to 2022, according to Zion Research. Flexible hybrid electronics and printed electronics enable new form factors and economics for a diverse set of applications. Examples include minimally invasive implantable systems that treat major depression and post-traumatic stress disorder (PTSD), the ability to repair or reproduce failed devices during space exploration, and head-up displays (HUDs) that will use ultra-thin holographic films to project transparent images on car windshields for safer driving.

“Global demand for technical expertise on materials, manufacturing and component technologies in FHE and printed electronics is rapidly growing,” said Melissa Grupen-Shemansky, CTO, Flexible Electronics and Advanced Packaging, SEMI. “2018FLEX offers the latest business and technology insights into applications such as flexible biosensors, flexible displays, drones, smart packaging, 3D printing and human-machine interfaces.”

2018FLEX will also showcase the latest technologies and solutions developed by contractors involved in the public/private research and development funding programs in FlexTech, NanoBio Manufacturing Consortium (NBMC), and NextFlex.

Keynotes headlining 2018FLEX will include:

  • Cortera Neurotechnologies – Minimally invasive implantable biosensors for treating major psychiatric illnesses
  • NASA – In-Space Manufacturing, a multi-material Fab Lab for the International Space Station
  • Luminit – Holographic Optical Element technologies for automotive HUD
  • Panasonic – Flexible hybrid electronics applications for lithium-ion batteries
  • Draper Labs – Flexible drones

2018FLEX will also highlight these exciting technologies:

  • Bonbouton – Graphene-based smart insoles for preventative diabetic healthcare
  • PARC – Latest application projects in environmental monitoring, wearables and supply chain solutions
  • Tekscan – Thin, flexible, tactile sensing technology for intelligent surgical, diagnostic and home healthcare applications

About 2018FLEX

The Flexible Electronics Conference and Exhibition (2018FLEX), now in its 17th year, will be held at the Hyatt Regency Monterey Hotel & Spa in Monterey. Highlights will include significant technical achievements, opportunities and challenges within the FHE and printed electronics industries.

Worldwide PC shipments totaled 71.6 million units in the fourth quarter of 2017, a 2 percent decline from the fourth quarter of 2016, according to preliminary results by Gartner, Inc. For the year, 2017 PC shipments surpassed 262.5 million units, a 2.8 percent decline from 2016. It was the 13th consecutive quarter of declining global PC shipments, as well as the sixth year of annual declines. However, Gartner analysts said there were some signs for optimism.

“In the fourth quarter of 2017, there was PC shipment growth in Asia/Pacific, Japan and Latin America. There was only a moderate shipment decline in EMEA,” said Mikako Kitagawa, principal analyst at Gartner. “However, the U.S. market saw a steep decline, which offset the generally positive results in other regions.

“The fourth quarter results confirmed again that PCs are no longer popular holiday gift items. This does not mean that PCs will disappear from households,” Kitagawa said. “Rather, the PC will become a more specialized, purpose-driven device. PC buyers will look for quality and functionality rather than looking for the lowest price, which will increase PC average selling prices (ASPs) and improve profitability in the long run. However, until this point is reached, the market will have to go through the shrinking phase caused by fewer PC users.”

HP Inc. moved into the No. 1 position in the fourth quarter of 2017, as its shipments grew 6.6 percent, and its market share totaled 22.5 percent (see Table 1). The company showed year-over-year growth in all regions, including the challenging U.S. market. For the fourth consecutive quarter, Lenovo experienced a decline in shipments. Lenovo had moderate growth in EMEA and Asia/Pacific, but shipments declined in North America.

Table 1
Preliminary Worldwide PC Vendor Unit Shipment Estimates for 4Q17 (Thousands of Units)

Company

4Q17 Shipments

4Q17 Market Share (%)

4Q16 Shipments

4Q16 Market Share (%)

4Q17-4Q16 Growth (%)

HP Inc.

16,076

22.5

15,084

20.7

6.6

Lenovo

15,742

22.0

15,857

21.7

-0.7

Dell

10,841

15.2

10,767

14.7

0.7

Apple

5,449

7.6

5,374

7.4

1.4

Asus

4,731

6.6

5,336

7.3

-11.3

Acer Group

4,726

6.6

4,998

6.8

-5.4

Others

13,990

19.6

15,599

21.4

-10.3

Total

71,556

100.0

73,015

100.0

-2.0

Notes: Data includes desk-based PCs, notebook PCs and ultramobile premiums (such as Microsoft Surface), but not Chromebooks or iPads. All data is estimated based on a preliminary study. Final estimates will be subject to change. The statistics are based on shipments selling into channels.
Source: Gartner (January 2018)

Dell’s shipments grew slightly in the fourth quarter of 2017. Dell did well in EMEA, Asia/Pacific and Latin America, but it had weak results in North America. Generally, Dell has put a higher priority on profitability over market share.

Steep PC shipment decline in the U.S.

In the U.S., PC shipments surpassed 15.2 million units in the fourth quarter of 2017, an 8 percent decline from the fourth quarter of 2016 (see Table 2). Four of the top five vendors experienced a decline in U.S. PC shipments in the fourth quarter of 2017. HP Inc. was the only vendor to increase shipments in the quarter. The decline was attributed to weak consumer demand despite holiday season sales.

“U.S. consumer confidence was high in the fourth quarter of 2017, but that did not influence PC demand. U.S. holiday sales were filled with popular products, such as voice-enabled speakers, and newly released smartphones,” Kitagawa said. “PCs simply could not compete against these gift items during the holiday season. We did see some consistent growth of gaming and high-end PCs.”

Table 2
Preliminary U.S. PC Vendor Unit Shipment Estimates for 4Q17 (Thousands of Units)

Company

4Q17 Shipments

4Q17 Market Share (%)

4Q16 Shipments

4Q16 Market Share (%)

4Q17-4Q16 Growth (%)

HP Inc.

5,130

33.7

5,049

30.5

1.6

Dell

3,691

24.3

4,209

25.4

-12.3

Apple

1,972

13.0

2,003

12.1

-1.6

Lenovo

1,792

11.8

2,344

14.2

-23.6

Acer Group

587

3.9

661

4.0

-11.2

Others

2,042

13.4

2,276

13.8

-10.3

Total

15,214

100.0

16,543

100.0

-8.0

Notes: Data includes desk-based PCs, notebook PCs and ultramobile premiums (such as Microsoft Surface), but not Chromebooks or iPads. All data is estimated based on a preliminary study. Final estimates will be subject to change. The statistics are based on shipments selling into channels.
Source: Gartner (January 2018)

PC shipments in EMEA totaled 21.8 million units in the fourth quarter of 2017, a 1.4 percent decline year over year. PC demand in the U.K. was still ailing and unit shipments into Germany were weaker than expected. PC revenue is expected to be up year over year in Western Europe. The rise in ASPs is due to currency fluctuations, the need for vendors to offset rising component costs, and a product-mix shift toward higher-value items, such as gaming systems and high-performing notebooks.

The Asia/Pacific PC market totaled 25 million units in the fourth quarter of 2017, a 0.6 percent increase from the fourth quarter of 2016. The consumer market stabilized with fourth-quarter online promotions in many countries, which drove demand for gaming PCs and thin and light notebooks. China experienced its first positive PC shipment growth since the first quarter of 2012. The success of the 11.11 shopping festival and the continuing demand for PCs in the commercial market drove the China PC market to 1.1 percent growth in the quarter.

PC market consolidation in 2017

For the year, worldwide PC shipments totaled 262.5 million units in 2017, a 2.8 percent decrease from 2016 (see Table 3). As the PC industry continues to consolidate, the top four vendors in 2017 accounted for 64 percent of global PC shipments. In 2011, the top four vendors accounted for 45 percent of PC shipments.

“The top vendors have taken advantage of their volume operations to lower production costs, pushing small to midsize vendors out of the market,” Kitagawa said.

Table 3
Preliminary Worldwide PC Vendor Unit Shipment Estimates for 2017 (Thousands of Units)

Company

2017

Shipments

2017 Market

Share (%)

2016

Shipments

2016 Market Share (%)

2017-2016 Growth (%)

HP Inc.

55,162

21.0

52,734

19.5

4.6

Lenovo

54,714

20.8

55,951

20.7

-2.2

Dell

39,871

15.2

39,421

14.6

1.1

Apple

19,299

7.4

18,546

6.9

4.1

Asus

17,967

6.8

20,496

7.6

-12.3

Acer Group

17,088

6.5

18,274

6.8

-6.5

Others

58,435

22.3

64,683

23.9

-9.7

Total

262,537

100.0

270,106

100.0

-2.8

Notes: Data includes desk-based PCs, notebook PCs and ultramobile premiums (such as Microsoft Surface), but not Chromebooks or iPads. All data is estimated based on a preliminary study. Final estimates will be subject to change. The statistics are based on shipments selling into channels.
Source: Gartner (January 2018)

These results are preliminary. Final statistics will be available soon to clients of Gartner’s PC Quarterly Statistics Worldwide by Region program. This program offers a comprehensive and timely picture of the worldwide PC market, allowing product planning, distribution, marketing and sales organizations to keep abreast of key issues and their future implications around the globe.

 

United Microelectronics Corporation (NYSE:UMC; TWSE:2303) (“UMC”), a global semiconductor foundry, today announced that the company has filed a patent infringement lawsuit against Micron Semiconductor (Xi’an) Co., Ltd. and Micron Semiconductor (Shanghai) Co., Ltd. in the Fuzhou Intermediate People’s Court of the People’s Republic of China (PRC). The lawsuit covers three areas that allegedly infringe upon UMC’s patent rights in China, including specific memory applications that relate to DDR4, SSD and memory used in graphics cards.

In the complaint, UMC has requested the court to order the defendant(s) to stop manufacturing, processing, importing, selling and intending to sell the allegedly infringing products, destroy all inventory and related molds and tools and demand that Micron compensate the company for a total amount of RMB 270 million in damages.

UMC has devoted a great deal of resources and manpower to researching and developing semiconductor manufacturing technology. Its achievements can be applied to logic chips or memory chips (DRAM), and the company has applied for patents in various countries while continuing to monitor these patents as market conditions evolve. After conducting an in-depth review, UMC found that Micron’s products sold in mainland China did indeed infringe upon the patent rights of the company, and thus patent infringement litigation has been pursued in order to obtain fair judgment.

Luc Van den Hove, president and CEO of imec

Luc Van den Hove, president and CEO of imec

SEMI today announced that Luc Van den hove, president and CEO of imec, has been selected as the 2018 recipient of the SEMI Sales and Marketing Excellence Award, inspired by Bob Graham. He will be honored for outstanding achievement in semiconductor equipment and materials marketing during ceremonies at ISS 2018 on January 17 in Half Moon Bay, California.

Van den hove will receive the 21st SEMI Sales and Marketing Excellence Award for his contributions and leadership in consortia that made the imec model of collaborative research using pooled infrastructure self-sustaining. The model enables companies of all sizes and position in the value chain to participate in collaborative research that advances industry technology.

Inspired by the power of technology to improve lives, Van den hove transformed research from its focus on participation cost to an emphasis on collaboration to produce greater value. Under his leadership, imec brings together brilliant minds from established companies, startups and academia worldwide to work in a creative and stimulating environment with imec serving as their trusted partner. imec’s international research and development drives innovations in nanoelectronics and digital technologies by leveraging its world-class infrastructure and local and global ecosystem of diverse partners to accelerate progress towards a connected, sustainable future. Van den hove joined imec in 1984 and has led the technology innovation hub since 2009.

“Luc Van den hove is recognized both for his innovative marketing leadership and his resolve to deepen industry collaboration for the common good. Today, SEMI and its membership honor Van den hove for his contributions to the success of the semiconductor manufacturing industry,” said Ajit Manocha, president and CEO of SEMI.

The SEMI Sales and Marketing Excellence Award was inspired by the late Bob Graham, the distinguished semiconductor industry leader, who was a member of the founding team of Intel. Graham also helped establish industry-leading companies such as Applied Materials and Novellus Systems. The Award was established to honor individuals for the creation and/or implementation of marketing programs that enhance customer satisfaction and further the growth of the semiconductor equipment and materials industry.

Eligible candidates are nominated by their industry peers and selected after due diligence by an award committee. Previous recipients of this SEMI award include: Toshio Maruyama (2017), Jim Bowen (2016), Terry (Tetsuro) Higashi (2015), Winfried Kaiser (2014), Joung Cho (JC) Kim (2013), G. Dan Hutcheson (2012), Franz Janker (2011), Martin van den Brink (2010), Peter Hanley (2009), Richard Hong (2008), Richard E. Dyck (2007), Aubrey (Bill) C. Tobey (2006), Archie Hwang (2005), Edward Braun (2004), Shigeru (Steve) Nakayama (2003), Jerry Hutcheson and Ed Segal (2002), Jim Healy and Barry Rapozo (2001), and Art Zafiropoulo (2000).

Boston Semi Equipment (BSE), a global semiconductor test handler manufacturer and provider of test automation technical services, announced today that it has received a multisystem order for its Zeus gravity feed systems for handling pressure MEMS devices. The order was placed by a leading manufacturer of tire pressure monitoring system sensors, which selected BSE’s Zeus pressure MEMS solution based on its higher throughput capability.

“This order demonstrates how our innovative MEMS solution is being recognized by the market as a superior alternative for its pressure MEMS testing needs,” said Mike Kerrigan, vice president of sales for BSE. “Our solution dramatically improves throughput by achieving our customers’ desired pressure set points faster and more accurately than others, which in turn makes Zeus’ pressure test handler for MEMS devices a winning investment.”

The Zeus system is a tri-temperature handler that can be configured with up to eight test sites. Cold temperature testing is achieved using LN2 or a BSE-designed, two-stage chiller, the MR2. Zeus offers the features and performance needed by today’s test cells at a more affordable price point.