Category Archives: 3D Integration

GLOBALFOUNDRIES today announced that Arbe Robotics has selected GF’s 22FDX® process for its groundbreaking patented imaging radar that will achieve fully automated system capabilities and enable safer driving experiences for autonomous vehicles.

Arbe Robotics’ radar is the first in the world to show real-time 1 degree resolution and provide the required enhancements for sensors and ADAS technologies. Arbe’s goal is to build a sensing system with high resolution and zero false alarms, so vehicles will be able to make decisions relying exclusively on the data provided by the radar. Leveraging GF’s 22FDX FD-SOI technology, the new chipset is increasing the amount of transmitting and receiving channels on a chip and allowing for better integration to Arbe’s proprietary processor.

The rise of autonomous driving is changing the automobile semiconductor market, which is expected to grow to an estimated $54 billion by 2023. This is driven by a need for new technologies that promise to enhance the driving experience, such as 360-degree surround view monitoring, which requires high resolution and long-range capabilities. GF’s 22FDX process provides the superior RF performance, power consumption, low noise, and high digital density to increase range and improve resolution for these applications.

As the first company to demonstrate ultra-high-resolution at a wide field of view, Arbe Robotics’ radar technology can detect pedestrians and obstacles at a range of 300 meters, in any weather and lighting conditions. The processor creates a full 3D shape of the objects and their velocity, and classifies targets using their radar signature.

“Arbe Robotics’ imaging radar is optimized for providing a real-time 4D picture of the environment at ultra high resolution,” said Kobi Marenko, CEO of Arbe Robotics. “The collaboration with GF is a significant step towards archiving the high-performance level required for autonomous driving safety. With over a decade of automotive industry experience, GF’s 22FDX delivers a performance on-demand, energy-efficient solution for our current and future radar technology needs.”

“The trend of autonomous driving is progressing rapidly, and with it is the need for high-resolution radar. The future will rely on a mix of real-time maps, advanced navigation software, and live data from vehicle sensors,” said Mark Granger, vice president of automotive at GF. “That’s why GF is pleased Arbe Robotics has chosen our 22FDX platform, together bringing valuable attributes that support the explosive growth of the autonomous driving industry.”

GF’s 22FDX platform is a part of the company’s AutoPro™ solutions, which provides customers with additional access to manufacturing services that support the full range of AEC-Q100 quality grades from Grade 2 to Grade 0 to minimize certification efforts and speed time-to-market.

SPTS Technologies, an Orbotech company and a supplier of advanced wafer processing solutions for the global semiconductor and related industries, announced today that it has been awarded the coveted Queen’s Award for Enterprise in Innovation 2018. The award recognizes SPTS’s development of novel physical vapor deposition (PVD) process solutions for Fan-Out Wafer Level Packaging (FOWLP) of semiconductor devices. Some of the advanced features and functionality developed for SPTS’s 300mm Sigma®fxP PVD system was made possible with funding assistance from a Welsh Government R&D grant. In addition to assessing the degree of innovation, the judging panel also evaluated SPTS on its corporate responsibility, which included employee affairs, customer and supplier relationships, and its impact on the environment and contribution to society.

“We are extremely proud to be recognized with the Queen’s Award for Enterprise in Innovation,” stated Kevin Crofton, Corporate Executive Vice President at Orbotech and President of SPTS Technologies. “We provide advanced wafer processing equipment to the world’s leading semiconductor and microelectronics manufacturers, and an ongoing program of research and development coupled with our ability to commercialize our innovation has been key to building and sustaining a profitable business. This award belongs to our entire global organization – from those directly involved in the development of our advanced PVD solutions for the fast growing FOWLP application sector, to those who sold, manufactured, installed and supported the many 300mm Sigma systems that we’ve shipped into our customer base.”

Mr Crofton added, “The success of our wafer processing solutions for advanced packaging is a testament to the quality and competitiveness of UK developed technologies and products in the global markets. We are also very pleased to share credit for this award with the Welsh Government who demonstrated their commitment with the R&D grant that helped fund this and other advanced packaging development programs here at SPTS.”

Economy Secretary, Ken Skates said: “Huge congratulations to SPTS on winning another Queens Award for Enterprise and Innovation. SPTS is a prominent global business in South East Wales and an increasingly successful exporter, and this prestigious award is a well-deserved recognition of the company’s hard work and innovation.”

“The Welsh Government is proud to work with dynamic and forward thinking companies such as SPTS and we are pleased to have supported the company’s project to design and develop advanced packaging processes for semiconductors. There is no doubt that companies like SPTS are increasingly vital to our economy which is why my Economic Action Plan, which was published in December, seeks to support businesses to innovate, introduce new products and services and rise to the challenges of the future.”

The Queen’s Awards for Enterprise are the UK’s most prestigious business awards, given only to companies or individuals who are outstanding in their field. Previously known as the Queen’s Awards to Industry, the Queen’s Awards for Enterprise were introduced in 1966 to acknowledge businesses with outstanding performance in three categories – International Trade, Innovation and Sustainable Development.  The awards are open to any company operating in the UK and are announced annually on 21 April, The Queen’s birthday.

Technavio market research analysts forecast the global semiconductor assembly and packaging services market to grow at a CAGR of close to 5% during the period 2018-2022, according to their latest report.

In this report, Technavio highlights the advances in wafer size as one of the key emerging trends in the global semiconductor assembly and packaging services market. Since 2010, the semiconductor industry has seen a drastic transition in wafer size. To cut down costs by almost 20%-25%, the industry has shifted to large diameter wafers. Currently, the industry uses 300-mm wafers to manufacture ICs. As companies are investing a substantial amount in the construction and upgrading of fabs to manufacture 300-mm wafers, this trend is expected to continue during the forecast period.

However, the demand for 200-mm wafers will continue during the forecast period because semiconductor devices such as image sensors, microcontrollers, display drivers, and a few MEMS-based products like accelerometers still use 200-mm wafers for manufacturing. At the same time, the industry is planning to develop 450-mm wafer technology, which is expected to start during 2018-2019. This constant change in the wafer size will create the need for assembly and packaging services in the semiconductor industry.

In this report, Technavio analysts highlight the rising number of fabs as a key factor contributing to the growth of the global semiconductor assembly and packaging services market:

Rising number of fabs

Semiconductor fabs manufacture an array of semiconductor devices and components. These components are either designed in-house by IDMs or manufactured as per designs provided by the client to foundries. The need for silicon wafers to manufacture semiconductor components is increasing due to the rising application of these components in various emerging technologies such as IoT and AI. This will increase the need to develop more number of fabs. As the semiconductor foundry market is highly competitive, several companies are building new fabs.

According to a senior analyst at Technavio for semiconductor equipment, “The need for assembly and packaging services required for the timely manufacture of ICs is growing, due to the increasing demand for ICs in various emerging applications such as autonomous cars and robotics. Major foundries have announced various plans of constructing new fabs, which will be operational by 2019 onward.”

Global semiconductor assembly and packaging services market segmentation

This market research report segments the global semiconductor assembly and packaging services market into the following applications, including communication sector, computing and networking sector, industrial and automotive sector, and consumer electronics sector and key regions, including the Americas, APAC, and EMEA.

Of the four major applications, the communication sector held the largest market share in 2017, accounting for nearly 40% of the market. The market share for this application is expected to increase nearly 2% by 2022. The fastest growing application is industrial and automotive sector, which will account for nearly 24% of the total market share by 2022.

APAC was the leading region for the global semiconductor assembly and packaging services market in 2017, accounting for a market share of nearly 76%. By 2022, APAC is expected to continue dominating the market.

Nexperia, a developer of discretes, logic and MOSFET devices, today announced the successful completion of a refinancing of its current facilities with USD 800 million equivalent of senior credit facilities. This includes a significant proportion of Revolving Credit facility. The proceeds will be used to refinance existing outstanding debt and for Capex expenditure to fund future growth.

The facilities were arranged by Bank of America Merrill Lynch and HSBC, acting as Global Coordinators, and were syndicated by a group of nine global banks. The refinancing is fully supported by JAC Capital and Wise Road Capital, Nexperia’s two main shareholders, and provides a flexible financing package at very attractive terms to support the further growth of Nexperia going forward.

Comments from Frans Scheper, Nexperia’s CEO: “This is the first time that Nexperia has approached the financial markets as an independent company, so we are very pleased with the enthusiastic response. Refinancing the outstanding debt will result in significant savings and give us greater flexibility, while the extra credit will enable us to pursue our ambitions fully with investment in new facilities and manufacturing technology.”

Nexperia is a Netherlands-headquartered, global manufacturer of discrete semiconductor components. The company is investing in increasing its capacity and footprint, having recently made a significant expansion to its Guangdong Assembly and Test Facility in China.

SEMI, the industry association representing the global electronics manufacturing supply chain, and TechSearch International today reported that the global semiconductor packaging materials market reached $16.7 billion in 2017. While slower growth of smartphones and personal computers – the industry’s traditional drivers – is reducing material consumption, the slowdown was offset by strong unit growth in the cryptocurrency market in 2017 and early 2018. Flip chip package shipments into the cryptocurrency market, while providing a windfall to many suppliers, are not expected to remain at high levels.

The Global Semiconductor Packaging Materials Outlook shows that, despite growth in automotive electronics and high-performance computing, continuing price pressure and declining material consumption will constrain future material revenue growth to steady single-digits, with the materials market forecast to reach $17.8 billion in 2021. IC leadframes, underfill, and copper wire are among the materials segments that will see single-digit unit volume growth through 2021.

Laminate substrate suppliers participating in the sale of flip chip substrates for cryptocurrency saw volume increases in 2017, but this segment continues to be battered by increased use of multi-die solutions and the shift to wafer level packages (WLPs), including fan-out WLP, slowing growth. Wafer-level packaging (WLP) dielectrics and plating chemistry suppliers will experience stronger revenue growth as the adoption of advanced packaging continues.

Over the next several years, advances in the semiconductor materials market will present a number of opportunities driven by trends including:

  • Continued adoption of FO-WLP including FO-on-substrate solutions with high density geometries down to 2µm lines and spaces
  • Liquid crystal polymer (LCP) under consideration as a possible material option because of its good electrical performance and low moisture absorption, especially for mmWave applications such as 5G
  • Adoption of low-cost package solutions such as MIS and other routable-QFN technologies
  • PPF QFN volumes are rising with automotive applications, driving a requirement for roughened plating to deliver needed reliability
  • Expansion of photoresist plating capability for selective plating of leadframes
  • Thermally enhanced and high-voltage mold compounds for power and automotive devices
  • Thermally conductive die attach materials other than solder die attach for power applications

Report highlights include:

  • Laminate substrates represent the largest revenue segment of the materials market with more than $6 billion in sales for 2017.
  • Overall leadframe shipments are forecast to grow at a 3.9 percent CAGR from 2017 through to 2021, with LFCSP (QFN type) experiencing the strongest unit growth, an 8 percent CAGR.
  • Following five years of decline, gold wire shipments increased in both 2016 and 2017 though represent just 37 percent of the total bonding wire shipments in 2017.
  • Liquid encapsulant revenues totaled $1.3 billion in 2017 with single-digit expected through 2021. LED packaging applications are driving the revenue growth over the forecast period though downward pricing pressures are a constant in the market.
  • Die attach material revenues reached $741 million in 2017 with single digit growth to 2021. DAF materials will experience higher unit growth, though downward pricing trends continue.
  • Solder ball revenues reached $231 million in 2017. The revenue outlook depends on fluctuations in metal pricing.
  • The wafer-level plating chemical market was put at $263 million in 2017 with strong growth through 2021. RDL and Cu pillar will be the key growth segments.

SEMI and TechSearch International, Inc. teamed up again to develop the 8th edition of the Global Semiconductor Packaging Materials Outlook, a comprehensive market research study on the semiconductor packaging materials market. Interviews were conducted with more than 130 semiconductor manufacturers, packaging subcontractors, fabless semiconductor companies, and packaging material suppliers to gather information for the report. The report covers the following semiconductor packaging materials segments: substrates, leadframes, bonding wire, mold compounds, underfill materials, liquid encapsulants, die attach materials, solder balls, wafer level package dielectrics, and wafer-level plating chemicals.

Toshiba Electronic Devices & Storage Corporation (“Toshiba”) has released two new MOSFETs “TPHR7904PB” and “TPH1R104PB” housed in the small low-resistance SOP Advance (WF) package, as new additions to the automotive 40V N-channel power MOSFET series. Mass production starts today.

Fabricated using the latest ninth generation trench U-MOS IX-H process and housed in a small low-resistance package, the new MOSFETs provide low on-resistance and thus help reduce conduction loss. The U-MOS IX-H design also lowers switching noise compared with Toshiba’s previous design (U-MOS IV), helping to reduce EMI (Electromagnetic Interference).

The SOP Advance (WF) package adopts a wettable flank terminal structure, which enables AOI (Automated Optical Inspection) after soldering.

Applications

  • Electric power steering (EPS)
  • Load switches
  • Electric pumps

Features

  • Provides a maximum on-resistance, RDS(ON)max, of 0.79 mΩ from the use of the U-MOS IX-H process and the SOP Advance(WF) package.
  • Low-noise characteristics reduce electromagnetic interference (EMI).
  • Available in a small low-resistance package with a wettable flank terminal structure.

Main Specifications

(Unless otherwise specified, @Ta=25°C)

Part Number

Drain-Source
voltage
VDSS
(V)

Drain
current
(DC)
ID
(A)

Drain-Source
on-resistance

RDS(ON) max.(mΩ)

Built-in
Zener Diode
between
Gate-Source

 Series

@VGS=6V

@VGS=10V
TPH1R104PB 40 120 1.96 1.14 No U-MOS IX
TPHR7904PB 150 1.3 0.79 No U-MOS IX

By Emir Demircan, Senior Manager Advocacy and Public Policy, SEMI Europe

With its leading research and development hubs, materials and equipment companies and chipmakers, the EU is in a strategic position in the global electronics value chain to support the growth of emerging applications such as autonomous driving, internet of things, artificial intelligence and deep learning. Underpinning the European electronics industry’s competitive muscle requires a new EU-wide strategy aimed at strengthening the value chain and connecting various players. Specializing and investing in key application segments, such as automotive where the EU enjoys a central place at global level, is crucial to help European electronics industry hold its ground.  In parallel, Europe’s production capabilities need bolstered, requiring effective use of Important Projects of Common European Interest (IPCEI).

On research, development and innovation (RD&I), the upcoming Framework Programme 9 (FP9) must provide unprecedented collaboration and funding opportunities to Europe’s electronics players. Concerning small and medium enterprises (SMEs) and startups, it is vital that EU policies are aligned with global trends and small and young companies benefit from a business-friendly regulatory framework. And as an overarching action, building a younger, bigger and more diverse talent pipeline is paramount for Europe to innovate in the digital economy.

Laith Altimime, President at SEMI Europe, opening speech at ISS Europe 2018

Laith Altimime, President at SEMI Europe, opening speech at ISS Europe 2018

These were the clarion messages that emerged from the Industry Strategy Symposium (ISS) Europe organized by SEMI in March, an event that brought together more than 100 industry, research and government representatives for in-depth discussions on strategies and innovations for Europe to compete globally. Here are the key takeaways:

1) Build a strong electronics value chain with a focus on emerging demands

In recent years the EU has focused on beefing up semiconductor production in Europe within the 2020-25 window, starting with the EU 10|100|20 Electronic Strategy of 2013. The strategy aims to secure about 20 percent of global semiconductor manufacturing by 2020 with the help of € 10 billion in public and private funding and € 100 billion investment from the industry. Today, Europe is not nearly on track to achieving this target. Supply-side policies have done little to help grow the EU semiconductor industry. Now is the time to change our thinking.

To nourish the electronics industry in Europe, we need to shift our focus to demand. Semiconductors are a key-enabling technology for autonomous driving, wearables, healthcare, virtual and augmented reality (VR/AR), artificial intelligence (AI) and all other internet of things (IoT) and big data applications. To become a world leader in the data economy and energize its semiconductor industry, Europe needs to start by better understanding the evolution of data technologies and their requirements from electronics players, then design and implement an EU-wide strategy focused on strengthening collaboration within the value chain.

2) Specialize and invest in Europe’s strengths that are enabled by electronics

Jens Knut Fabrowsky, Executive VP Automotive Electronics at Bosch

Jens Knut Fabrowsky, Executive VP Automotive Electronics at Bosch

Fueled by increasing demand for smaller, faster and more reliable products with greater power, the global electronics industry has developed a sophisticated global value chain. Europe brings to this ecosystem leading equipment and materials businesses, world-class R&D and education organizations, and key microelectronics hubs throughout Europe that are home to multinationals headquartered both in and outside of the EU. Nevertheless, global competition is growing ever fiercer in the sectors where the European microelectronics industry is most competitive: automotive, energy, healthcare and industrial automation. In the future, Europe is likely to be more challenged between the disruptive business models of North America and the manufacturing capacity of East Asia. The European electronics industry must re-evaluate its strengths and set a strategic direction.

Make no mistake: Europe is in a strong position to advance its microelectronics industry. The EU already boasts leading industries that rely on advances made by electronics design and manufacturing. Take the automotive industry – crucial to Europe’s prosperity. Accounting for 4 percent of the EU GDP and providing 12 million jobs in Europe, according to the European Commission, the EU automotive industry exerts an important multiplier effect in the economy. Automotive is essential to both upstream and downstream industries such as electronics – a level of importance not lost on the EU’s GEAR 2030 Group. Since the 1980s, automotive industry components have increasingly migrated from mechanical to electrochemical and electronics.

Today, electronic components represent close to a third of the cost of an automobile, a proportion that will grow to as high as 50 percent by 2030 with the rise of autonomous and connected vehicles. Automotive experts anticipate that over the next five to 10 years, new cars will feature at least some basic automated driving and data exchange capabilities as electronics deepen their penetration into the automotive value chain. Europe’s leadership position and competitive edge in automotive are under threat by competitors across the world as they invest heavily in information and communications technologies (ICT) and electronics for autonomous driving and connected vehicles. Investing in next-generation cars will help the European electronics industry retain its strong competitive position, as will investments in other key application areas such as healthcare, energy and industrial automation where Europe is a global power.

3) Make better use of Important Projects of Common European Interest (IPCEI)

Microelectronics is capital-intensive, with a state-of-the-art fab easily costing billions of euros. That’s why countries around the world are making heavy government-backed investments to build domestic fabs. For instance, China’s “Made in China 2025” initiative, which establishes an Integrated Circuit Fund to support the development of the electronics industry, calls for 150 billion USD in funding to replace imported semiconductors with homegrown devices. In 2014, the European Commission adopted new rules to IPCEI, giving Member States a tool for financing large, strategically important transnational projects. IPCEI should help Member States fill funding gaps to overcome market failures and reinvigorate projects that otherwise would not have taken off. To fully benefit from the IPCEI, the industry requires Member States involved in a specific IPCEI to work in parallel and at the same pace and faster approvals of state-supported manufacturing projects.

4) Use FP9 to strengthen Europe’s RD&I capabilities

Panel Discussion on growing Europe in the global value chain. (L-R) Bryan Rice, GLOBALFOUNDRIES; James Robson, Applied Materials Europe; Joe De Boeck, imec; Leo Clancy, IDA Ireland; James O’Riordan, S3; Colette Maloney, European Commission; Moderator: Andreas Wild

Panel Discussion on growing Europe in the global value chain. (L-R) Bryan Rice, GLOBALFOUNDRIES; James Robson, Applied Materials Europe; Joe De Boeck, imec; Leo Clancy, IDA Ireland; James O’Riordan, S3; Colette Maloney, European Commission; Moderator: Andreas Wild

A top EU priority in recent years has been to enhance Europe’s position as a world leader in the digital economy. Fulfilling this mission requires an innovative electronics industry in Europe. To this end, FP9 should encourage greater collaboration between large and small companies to leverage their complementary strengths – the dynamism, agility and innovation of smaller companies and the ability of larger companies to mature and scale new product ideas on the strength of their extensive private funding instruments and testing and demonstration facilities. Also, future EU-funded research actions should prioritize electronics projects involving players across the value chain, starting with materials and equipment providers and spanning chipmakers, system integrators and players from emerging “smart” verticals such as automotive, medical technology and energy. FP9 should also play the pivotal role of setting clear objectives, increasing investments, and easing rules for funding. These measures would help expand the European electronics ecosystem, accelerate R&D results and defray the rising costs of developing cutting-edge solutions key to the growth of emerging industry verticals.

5) Support high-tech SMEs, entrepreneurship and startups to become globally competitive

European SMEs, the backbone of EU’s manufacturing, are already strong players in the global economy, making outsize contributions to Europe’s innovation. Yet more of Europe’s small and young businesses with limited resources are challenged in Europe’s regulatory labyrinth. Only by improving the European regulatory environment in a way that supports young and small businesses can Europe fulfill its vision of a dynamic electronics ecosystem and digital economy. Access to finance must also be easier, particularly as underinvested startups struggle under a European venture capital apparatus that is smaller and more fragmented than those in North America and Asia. Early-stage funding instruments such as bank loans are essential for young businesses but they often face barriers to finance due to the sophistication of their proposed business models that are difficult to be understood and supported by banks.

One answer is to better familiarize Europe’s financial sector with industrial SMEs and startups so they can co-develop financial tools that support the growth of small and young businesses. Also, the narrow European definition of SME with staff headcount limited to 250 block innovative companies from access to financial tools exclusively provided to SMEs. By contrast, the United States defines SMEs as businesses with as many as 500 employees, placing their EU counterparts at distinct funding disadvantage. EU should ensure that its SME policy is aligned with global trends and industry needs.

6) Create a bigger and more diverse talent pipeline with a hybrid skills set 

Europe’s world-class education and research capabilities help supply the electronics industry with skilled workforce. Yet the blistering pace of technology innovation calls for rapidly evolving skills sets, a trend that has led to worker shortages at electronics companies and left the sector fighting to diversify its workforce and strengthen its talent pipeline. The deepening penetration of electronics in AI, IoT, AR/VR, high-performance computing (HPC), cybersecurity and smart verticals is giving rise to a new set of skills that blend production technologies, software and data analytics. As more technologies converge, the gap between university education and business needs continues to widen.

One solution is work-based learning – allowing students to build job skills in a setting related to their career pathway. Encouraging higher female participation in STEM education programs at the high school and university levels is also a must to overcome the traditionally low number of females entering high technology. To build on its reputation as “a place to work” in the eyes of the international job seekers, Europe also needs a more flexible immigration framework to attract skilled labour to high-tech jobs.

Save the Date: Industry leaders, research and government representatives will meet again next year at the ISS Europe organized by SEMI on 28-30 April 2019 in Milan, Italy. More details regarding the event will be published soon on www.semi.org/eu.

ON Semiconductor (Nasdaq: ON) has introduced the industry’s first 1/1.7-inch 2.1 megapixel CMOS image sensor featuring ON Semiconductor’s newly developed 4.2μm Back Side Illuminated (BSI) pixels – the AR0221 delivers class-leading low light sensitivity for industrial applications.

The AR0221 offers exceptional 3-exposure line-interleaved High Dynamic Range (HDR) with a sensor resolution of 1936H x 1096V, supporting frame rates of 1080p at 30 fps and an outstanding Signal-Noise Ratio (SNR) across visible and near-infrared wavelengths. Its 16:9 ratio with vivid colors and high contrast make it ideal for demanding industrial applications.

Gianluca Colli, Vice President and General Manager, Consumer Solution Division of Image Sensor Group at ON Semiconductor, said: “The AR0221 represents the industry’s best CMOS image sensor in this class, thanks to its outstanding low light sensitivity and SNR performance. By including features like windowing, auto black level correction and an onboard temperature sensor, ON Semiconductor has produced an image sensor that will enable a new generation of security and surveillance cameras.”

The sensor offers dual data interfaces in the form of 4-lane MIPI CSI-2 and HiSPi SLVS. Designed to meet industrial-grade specifications, the AR0221 can operate in harsh outdoor environments where operating temperatures can range between -30°C and +85°C. Packaged in a durable, reliable and robust iBGA package with anti-reflection coating on its cover glass, the AR0221 is programmable through a simple two-wire serial interface.

Fueled by heavy government investment, IC packaging and testing in China generated $29 billion in revenue in 2017, making China the world’s largest consumer of packaging equipment and materials, according to SEMI’s recent China Semiconductor Packaging Industry Outlook report. The report, based on research conducted between July 2017 through the end of January 2018, also revealed that China’s IC packaging and testing industry is more mature than its IC manufacturing and design sectors, though IC packaging and testing revenue growth has slowed in recent years.

SEMI surveyed 87 semiconductor packaging- and assembly-related companies for the research report, including key semiconductor packaging manufacturers in China. More than 100 companies compete in China’s packaging and assembly market, including leading multinational companies and emerging domestic players. More than half of China’s packaging companies are located in the Yangzi delta region, while midwestern China has emerged as a hotbed for packaging plants.

Additional report highlights:

  • Compared to other world regions, China’s investments in IC packaging and testing saw the fastest growth over the past decade, with domestic manufacturers securing strong support from both national and local governments to ramp capacity and technical capabilities.
  • The top three domestic packaging companies – JCET, Huatian, and TFME – all entered the top 10 global OSAT rankings following expansions and acquisitions from 2012 to early 2016.
  • Packaging companies such as SPIL, TFME, NCAP continue to build new plants.
  • As a major manufacturing region for LED products, China has become more prominent within the semiconductor packaging industry. China’s LED product sector grew to $13.4 billion (half of IC packaging) in 2017.
  • In 2017, China accounted for about 26 percent of the global packaging materials market, with China’s packaging materials revenue forecast to exceed $5.2 billion in 2018.
  • In 2017, the China assembly equipment market reached $1.4 billion in revenue, remaining the world’s largest with 37 percent share.
  • In 2017, assembly equipment manufactured in China (including assembly equipment made by foreign-owned companies and JVs) accounted for 17 percent of China’s assembly equipment market.
  • With the fast growth in the semiconductor packaging market, domestic packaging materials suppliers are expanding with the industry and now starting to serve leading international packaging houses.

The SEMI report also elucidates the importance of both central and local government support, guidelines and policies on China’s semiconductor industry. The National Fund and local IC funds, created in 2014, and the Made in China 2025 policy provided a second boost to China’s IC industry growth. For packaging and testing enterprises, maintaining strong communications and relations with relevant government bodies and industry associations is essential to securing both political and financial support, in part because China’s semiconductor manufacturers and IC assembly and packaging companies are expected to purchase equipment and materials made in China.

 

Combined sales for optoelectronics, sensors and actuators, and discrete semiconductors (known collectively as O-S-D) increased 11% in 2017—more than 1.5 times the average annual growth rate in the past 20 years—to reach an eighth consecutive record-high level of $75.3 billion, according to IC Insights’ new 2018 O-S-D Report—A Market Analysis and Forecast for Optoelectronics, Sensors/Actuators, and Discretes. Total O-S-D sales growth is expected to ease back in 2018 but still rise by an above average rate of 8% in 2018 to $81.1 billion, based on the five-year forecast of the new 375-page annual report, which became available this week.

In 2017, optoelectronics sales recovered from a rare decline of 4% in 2016, rising 9% to $36.9 billion, while the sensors/actuators market segment registered its second year in a row of 16% growth with revenues climbing to $13.8 billion, and discretes strengthened significantly, increasing 12% to $24.6 billion.  The new O-S-D Report forecast shows optoelectronics sales growing 8% in 2018, sensors/actuators rising 10%, and discretes growing 5% this year (Figure 1).

Figure 1

Figure 1

Between 2017 and 2022, sales in optoelectronics are projected to increase by a compound annual growth rate (CAGR) of 7.3% to $52.4 billion, while sensors/actuators revenues are expected to expand by a CAGR of 8.9% to $21.2 billion, and the discretes segment is seen as rising by an annual rate of 3.1% to $28.7 billion in the final year of the report’s forecast.  In the five-year forecast period, O-S-D growth will continue to be driven by strong demand for laser transmitters in optical networks and CMOS image sensors in embedded cameras, image recognition, machine vision, and automotive applications as well as the proliferation of other sensors and actuators in intelligent control systems and connections to the Internet of Things (IoT).  Power discretes (transistors and other devices) are expected to get a steady lift from the growth in mobile and battery-operated systems as well as good-to-modest global economic growth in most of the forecast years through 2022, the report says.

Combined sales of O-S-D products accounted for about 17% of the world’s $444.7 billion in total semiconductor sales compared to less than 15% in 2007 and under 13% in 1997.  Since the mid-1990s, total O-S-D sales growth has outpaced the much larger IC market segment because of strong and relatively steady increases in optoelectronics and sensors. However, this trend was reversed recently mostly due to a 77% surge in sales of DRAMs and 54% jump in NAND flash memory in 2017.

The 2017 increase for total O-S-D sales was the highest growth rate in the market group since the 37% surge in the strong 2010 recovery year from the 2009 semiconductor downturn.  In addition, 2017 was the first year since 2011 when all three O-S-D market segments reached individual record-high sales, says IC Insights’ new report.  The 2018 O-S-D Report also shows that sales of sensor and actuator products made with microelectromechanical systems (MEMS) technology grew 18% in 2017 to a record-high $11.5 billion.