Category Archives: Wafer Level Packaging

A main focus of this year’s Electronic Components and Technology Conference (ECTC), held this week in San Diego, is 3D integration and through silicon vias (TSVs).  “The biggest trend for the last couple of years has been 3D and TSV and it continues to be that way,” said David McCann of GLOBALFOUNDRIES and ECTC conference chair.  This year, the conference features a set of sessions specifically on 3D TSVs, with minimal overlap.  There’s also an additional session specifically on interposers, otherwise known as 2.5D. “The industry really wants to see 2.5D happen as an easier way to do 3D before all the 3D tools are in place,” McCann said. “The struggle is over how much is an interposer going to cost.”

Presently, that struggle appears to be between glass and silicon, where glass is a less expensive alternative. “Glass would be a cheaper approach to silicon interposers, but is limited to line space and via diameter,” McCann said. “Glass is not able to get as dense as silicon.” He said there may be a bifurcated market on interposers, where the high end is on silicon, and the low end is on glass. High end applications are devices such as microprocessors, which need high density, 1 micron lines and spaces. Low end devices are capabilities such as RF.  

In terms of when TSVs will move into volume production for mainstream applications, McCann said that RF devices that already have TSVs because they have backside contact. Next, memory devices are in line to for TSV production. “I think there will be more and more memory stacks,” he said. Fabricating a memory stack internally for a memory company is easy (at least compared to alternative approaches) in that it doesn’t require an outside standard to be able to do the connection between the devices. “Next will be wide I/O or whatever wide I/O morphs into, maybe wide I/O2, where you get an apps processor with a wide I/O DRAM on top of it,” McCann said. “I think we’ll see those starting in 2013, first products in the industry and 2014 for adoption into 20nm. And then, following that, it’s very dependent upon standards. Wide I/O standard is critical for getting multiple memory suppliers to supply memory or a consuming company to use multiple suppliers,” he said.  “Standards are going to enable products and those first 3D products are going to use devices that already exist and put TSVs into them.”

The real potential of 3D integration will come around 2017 or 2018, McCann believe, when heterogeneous stacks with different devices with different functions, such as memory, digital, analog , RF and power, are integrated in a stack. “There will be design tools that optimize the design of those devices for placement of blocks, TSVs and bumps  for optimal performance. In the first products, we won’t have so much optimization, but more enablement, and then where we all really want to get to is that optimization of performance, “ McCann said. “What that will look like is say a bit of memory just above a processing cell, right where you want it. Or the analog the right where you want it to be placed with this very short vertical interconnect to the circuitry that it needs to communicate with. We’ll get to optimal block placement when the tools start getting available to help us co-design devices from different manufacturers for optimal performance.”  

McCann acknowledged that testing these complex 3D stacks will be a major challenge, saying is revolves very much around IP. “If you think about DRAM and how it’s tested, it’s all internal to the DRAM company and it’s very tightly protected IP. Nobody wants to let that outside, understandably. Then you start thinking about 2.5D and 3D where you’ve got integrated memory – how do you do that? The assembly of those is not going to be at the memory manufacturer,” he said.

McCann believe stacked memory will evolve in two stages. The first stage will be it will be shipped as a completed component so that the memory company can continue to adhere to the business model of shipping a completed, tested, repaired device — a know good die.” That small stack will be placed on an apps processor for 3D, or on an interposer for 2.5D,” he said. The second part of it is what IP is needed for both the microprocessor and the memory to enable test. “We’ll start seeing test IP blocks from the foundries and the memory companies to enable test by using the processor to test the memory . I think we’re still exploring what that looks like. I can’t tell you what that’s going to end up looking like, but it’s clear that we’ve got to enable that together to enable the products,” McCann said.  

May 29, 2012 — Growth in handheld, Internet-connected electronic devices — smartphones and tablets — and resurgent automotive demand are increasing IC demand. In turn, increased demand for product functionality is driving up IC packaging revenue faster — a 9.8% compound annual growth rate (CAGR) — than IC unit growth — 7.3% CAGR 2010-2016, says New Venture Research (NVR).

Figure. IC device and packaging revenue forecast ($M), 2010-2016. SOURCE: New Venture Research.

Handheld electronics will boost the growth of special purpose logic (SPL) communications chips by 16.7% CAGR revenue through 2016, versus 3.5% CAGR in units. Packages for mobile components are dominated by field-programmable gate array (FPGA) and quad flat-pack no-lead (QFN) designs. These 2 package structures are at opposite ends of the pricing structure. The third most popular packaging type, quad flat pack (QFP), is decreasing in usage over time. These devices are expected to have a 14.8% CAGR in revenue through 2016.

Wireless infrastructure products are also in high demand, which is helping boost consumption for standard cell and programmable logic device (PLD) chips. These devices will grow at a CAGR of 16.1% in terms of revenue through 2016, while the device units are projected at 15%. High I/O BGAs are the package of choice over the forecast period — package revenue growth is projected to be slightly higher, at 16.3% CAGR through 2016.

Logic chips are in demand for a host of products, pushing 32-bit MCUs to an 11.1% CAGR unit demand, although only 4.7% device revenue CAGR, through 2016. QFPs and ball grid arrays (BGAs) are the highest-demand package designs for these chips, although the QFP is waning in favor of the BGA. Thus, the package revenue is growing at a CAGR of 12.8% through 2016 for 32-bit MCUs.

This information is included in the newly released report

May 29, 2012 — Semiconductor assembly and test services (SATS) provider Advanced Semiconductor Engineering Incorporated (ASE, TAIEX:2311, NYSE:ASX) opened its Phase 3 manufacturing facility in Weihai, Shangdong province, China, boosting discrete packaging and test capacity.

The 5,120sq.m. building offers 30,560sq.m. of floor space, and will require an additionally 2,000 employees in engineering, development, and operations at ASE. Weihai

May 23, 2012 – BUSINESS WIRE — Mitsubishi Electric Corporation (TOKYO:6503) developed a prototype forced-air-cooled three-phase 400V output inverter with all silicon carbide (SiC) power modules that has a power density of 50kVA per liter.

Mitsubishi Electric developed low resistance and higher power density by directly bonding power semiconductor chip leads to the main terminals, eliminating the use of conventional high-resistance aluminum lead wires. The module

May 19, 2012 — Amkor Technology Inc. (NASDAQ:AMKR) plans to build a state-of-the-art factory and global research and development center in the Incheon Free Economic Zone, which is located in the greater metropolitan area of Seoul, Korea. The new factory and R&D center will focus on the design, development and full scale production of innovative semiconductor packaging and test services for leading semiconductor and electronic manufacturing companies.

May 16, 2012 – BUSINESS WIRE — Mixed-signal IC maker Silicon Laboratories Inc. (NASDAQ:SLAB) introduced a microcontroller (MCU) die sales program with a minimum order quantity of 1 wafer.

The program is available for the company

May 11, 2012 — CMOS image sensors (CIS) are breaking sales records again, after several years without upward momentum, reports IC Insights. New portable systems and embedded imaging are lifting CIS to $6.3 billion in 2012 and new record sales each year through 2016, shows IC Insights’ 2012 Optoelectronics, Sensors/Actuators, and Discretes (O-S-D) Report.

Also from the report:Optoelectronics, sensors, and discretes saw record year in 2011

Camera-equipped portable electronics — tablets and smartphones among them — are contributing consistent strong CIS sales. CIS are also going into embedded digital-imaging applications, being designed into automobiles, medical equipment, security networks, and other vision-recognition systems.

Figure. CMOS image sensor growth through 2016. SOURCE: IC Insights.

CMOS image sensors will grow from $4.5 billion in 2010, $5.8 billion in 2011, to $6.3 billion in 2012, a new record. 2016 promises 10.8 billion in CMOS image sensor sales. 2011 marked the first back-to-back annual sales increase in CIS since 2006. CIS faced problems from the global recession and camera-phone inventory corrections in the past decade, IC Insights notes. After a rapid rise with the introduction and adoption of camera-phones and web cams, CIS hit a compound annual growth rate (CAGR) of 5% 2006-2011, low compared to the forecast 13% CAGR for 2012-2016.

In 2006, CMOS image sensors were in oversupply, and computer-embedded cameras and camera-phones were matured. Numerous CMOS image sensor manufacturers closed or sold their image sensor businesses.

Today, intense competition among leading CIS suppliers is on the rise again, IC Insights reports, with new applications fueling growth. Sony (#3 CIS supplier in 2011) and Toshiba (#5) are increasing fab capacity for products on 300mm wafers. Samsung (#2) is also boosting its 300mm capacity for image sensors. Fabless companies OmniVision (#1) and Aptina Imaging (#6) are under pressure to snap up 300mm foundry capacity for their CIS products. STMicroelectronics (#4) is also under the gun to move production from 200mm to 300mm wafers.

Automotive systems are the fastest-growing CMOS image sensor application, shows the 2012 O-S-D Report, with sales reaching $1.8 billion in 2016, 17% of the total market for CIS. With moderated growth, camera cellphones remain the largest CMOS image sensor application, with $5.4 billion (50% of total) in 2016 sales expected. In 2011, 72% of CIS sales were for camera phones. Standalone digital still cameras and video camcorders represent growth potential for CMOS devices, which are replacing charge-coupled device (CCD) image sensors in these systems, but this market is shrinking as cameras in phones improve, shows the new O-S-D Report.

The 340-page 2012 edition of the O-S-D Report continues to expand IC Insights’ coverage of the semiconductor industry with detailed analysis of trends and growth rates in the optoelectronics, sensors/actuators, and discretes market segments. The report contains a detailed forecast of sales, unit shipments, and selling prices for more than 30 individual product types and categories through 2016. Learn more at www.icinsights.com.

May 4, 2012 — Semiconductor packaging and test services provider Carsem will assemble and further develop light-emitting diode (LED) packaging technologies, partnering with a key customer.

Carsem has begun assembling and qualifying high-brightness silicon-substrate LED arrays and will ramp high-volume, full turn-key manufacturing services, including electrical testing, laser mark, and tape-and-reel, in early 2012.

To enable standard mass production, Carsem deployed matrix substrate design; auto die attach, wire bond, and high reflection coating dispense; compression molding through an automold system; substrate-mapping; and bin sort per test mapping on the LED packages.

Carsem

May 3, 2012 – BUSINESS WIRE — Micropelt has raised EUR6.5 million for the roll-out and global expansion of its thin-film thermoelectric energy harvesting technology: EUR5 million by Ludgate Environmental Fund (LEF); EUR1 million from the Fund of Mitsubishi UFJ Capital (MUCAP); and EUR0.5 million by the existing shareholders IBG/Goodvent, KfW, L-Bank and SHS.

Micropelt’s thermal micro energy harvesting technology, which uses waste heat to create electricity, will be rolled out to high-growth cleantech markets globally, with focus in Europe and Japan. The microchip-sized device displaces batteries in automated equipment and has multiple domestic and industrial applications, such as radiator valves, industrial automation and remote monitors that assess the condition of equipment.

Bill Weil, CIO of Ludgate Investments Limited, the Investment Adviser to LEF, praised the elimination of battery maintenance and disposal.

Yoshihiro Hashimoto, president of Mitsubishi UFJ Capital Co., Ltd., noted that consistent R&D positioned Micropelt for production of leading thermoelectric products.

Micropelt opened the thin-film thermoelectric production facility in June 2011 in Halle, Germany. Since then the company has been focused on increasing production volumes and reducing per unit cost. Fritz Volkert, CEO of Micropelt, said: "This investment provides Micropelt with a strong boost to our production capacity and the ability to drive the commercialization of our technology."

“After having opened their production site in 2011, the new investment round now enables Micropelt to expand globally,” said Hubertus Leonhardt, chairman of Micropelt’s supervisory board and Managing Partner of SHS Gesellschaft für Beteiligungsmanagement.

Micropelt has partnerships with major semiconductor players worldwide, and system integrators, in the field of industrial sensor equipment and intelligent radiator thermostats for heating systems. They also work with leading companies in the monitoring and maintenance of electronic distribution equipment. As part of the company’s global expansion and commercialization of its technology, Micropelt recently agreed on distribution relationships with Arrow in Europe, Tokyo Electronic Device and Hitachi High-Tech Materials Corporation in Japan.

Ludgate Environmental Fund invests in a diverse portfolio of late stage companies in the European cleantech sector. Actively managing its holdings, the Fund invests growth capital with a focus on waste and recycling; renewable energy; energy efficiency and water. Ludgate Environmental Fund launched in August 2007 and has assets under management of approximately £49.0 million as at 31 March 2012. The Fund is a Jersey domiciled closed-ended investment company, quoted on AIM under the symbols LEF.L for the shares and LEFW.L for the warrants. For more information www.ludgateenvironmental.com

Mitsubishi UFJ Capital (MUCAP) is VC arm of Mitsubishi UFJ Financial Group, originally established in 1974 by Mitsubishi Group companies, manages multiple funds with total capital approximately $500M. MUCAP has made cross-border type investments with selected global syndication partnerships. In this field, MUCAP is focusing companies which offering or developing technologies, products, solutions or services relevant to the Japanese market or companies, especially in TMT & Life Science sector. Further information www.mucap.co.jp/english/profile.html

Micropelt GmbH is a developer, producer and marketer of the world’s smallest thermal energy harvesting chips. The thermoelectric micro chips are based on a patented and scalable thin-film technology which reduces component size while maximising power density. The chips scavenge free electric power from waste heat to replace or recharge batteries in wireless sensor networks and micro actuators. Based in Germany, Micropelt employs 23 staff and opened its first production facility in June 2011. For more information, www.micropelt.com

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