SPIL

Post-Conference Report: SEMI Heterogeneous Integration SummitDemand for high-performance computing (HPC) chips is exploding. These super-speedy chips are critical for data centers and cloud computing infrastructures to support new performance-hungry technologies such as artificial intelligence (AI) and 5G. The challenge is for the devices and their multi-core architectures to couple high bandwidth density with low latency and high energy efficiency. Heterogenous integration offers a potential answer as an advanced packaging technology designed to meet these skyrocketing performance demands on HPC chips and open the door to a whole new world of 3D integrated circuits (ICs).So important are 3D ICs that Intel and TSMC representatives speaking at the recent Heterogeneous Integration Summit hosted by SEMI Taiwan in Taipei declared that the packaging technology will all but dictate the future of the industry. All told, 12 speakers from government, academia and a broad range of leading international companies from sectors including advanced packaging, design, manufacturing, silicon photonics, equipment and materials shared forward-looking strategies, the latest technologies and potential heterogeneous integration market opportunities. Koushik Banerjee, vice president, TMG, Assembly, and Test Technology Integration, at Intel pointed out that using heterogeneous integration for a single SiP (system-in-package) will deliver what the industry has long wanted by enabling multiple process nodes, more diverse silicon IP (intellectual property) and chip functionality, and chips that pair low energy with high frequency. Intel plans to announce its first Forveros 3D packaging product combining a 10nm HPC chiplet with a low-energy 22nm base die and stacked with memory on top. When asked about the future of advanced packaging technology, Banerjee said it will be very much about the combination of Foveros and its very own Embedded Multi-Die Interconnect Bridge (EMIB).For its part, TSMC, will continue to upgrade its CoWoS (Chip-on-Wafer-on-Substrate), InFO (Integrated Fan-out) and other 2.5D IC production solutions while developing 3D chip stacking technology such as SoIC and WoW (wafer-on-wafer). TSMC is ushering in a new age of 3D IC packaging, said Marvin Liao, Vice President, Backend Technology and Service Division, at TSMC. The company’s SoIC is based on Chip-on-Wafer concept, with the flexibility to support one-to-many or different process nodes, whereas its WoW integrates two wafers with solid yields that could be used for products of the same size or manufactured with mature process technology.Speakers also included representatives from ATOTECH, Lam Research, SPIL, Sigurd, Cadence, Grand Process Technology, ITRI (Industrial Technology Research Institute), Industrial Development Bureau, and Lee San-Liang, Distinguished Professor, Department of Electronic and Computer Engineering at National Taiwan University of Science and Technology all shared their perspectives on equipment, materials, and testing and how different industry value chains might contribute to the development of heterogeneous integration technology.Expected to be a key driver of the next wave of semiconductors, heterogeneous integration and related technologies – including 3D IC, FOWLP (Fan-out wafer-level packaging) / FOPLP (Fan-out panel-level packaging), silicon photonics, Micro LED, compound semiconductor, automated optical inspection and SLT (system level testing) – will be a key focus at SEMICON Taiwan 2019, September 18 to 20 in Taipei. The Heterogeneous Integration Innovation Zone – along with featured international programs such as SiP Global Summit, Strategic Materials Conference, the Smart Data Summit and the Smart Automotive Summit – will gather key industry players to reveal the latest technology breakthroughs and market trends.Emmy Yi is a senior marketing specialist at SEMI Taiwan.

New SEMI Taiwan Testing Committee to strengthen the last line of defense to ensure the reliability of advanced semiconductor applications.Mobile, high-performance computing (HPC), automotive, and IoT – the four future growth drivers of semiconductor industry, plus the additional boost from artificial intelligence (AI) and 5G – will spur exponential demand for multi-function and high-performance chips. Today, a 3D IC semiconductor structure is beginning to integrate multiple chips to extend functionality and performance, making heterogeneous integration an irreversible trend. As the number of chips integrated in a single package increases, the structural complexity also rises. Not only will this make identifying chip defects harder, but the compatibility and interconnection between components will also introduce uncertainties that can undermine the reliability of the final ICs. Add to these challenges the need for tight cost control and a faster time to market, and it’s clear that semiconductor testing requires disruptive, innovative change. Traditional final-product testing focusing on finished components is now giving way to wafer- and system-level testing.In addition, the traditional notion of design for testing, an approach that enhances testing controllability and observability, is now coupled with the imperative to test for design, which emphasizes drawing analytics insights from collected test data to help reduce design errors and shorten development cycles. Going forward, the relationship among design, manufacturing, packaging, and testing will no longer be un-directional. Instead, it will be a cycle of continuous improvement.This paradigm shift in semiconductor testing, however, will also create a need for new industry standards and regulations, elevate visibility and security levels for shared data, require the optimization of testing time and costs, and lead to a shortage of testing professionals. Solving all these issues will require a joint effort by the industry and academia. "With leading technologies and $4.7 billion in market value, Taiwan still holds the top spot in global semiconductor testing market," said Terry Tsao, President of SEMI Taiwan. "When testing extends beyond the manufacturing process, it can play a critical role in ensuring quality throughout the entire life cycle from design and manufacturing to system integration while maintaining effective controls on development costs and schedules. Taiwan's semiconductor industry is in dire need of a common testing platform to enable the cross-disciplinary collaboration necessary for technical breakthroughs."The SEMI Taiwan Testing Committee was formed to meet that need, gathering testing experts and academics from MediaTek, Intel, NXP Semiconductors, TSMC, UMC, ASE Technology, SPIL, KYEC, Teradyne, Advantest, FormFactor, MJC, Synopsys, Cadence, Mentor, and National Tsing Hua University to collaborate in building a complete testing ecosystem. The committee addresses common technical challenges faced by the industry and cultivates next-generation testing professionals to enable Taiwan to maintain its global leadership in semiconductor testing.The SEMI Taiwan Testing Platform spans communities, expositions, programs, events, networking, business matching, advocacy, and market and technology insights. For more information about the SEMI Taiwan Testing platform, please contact Elaine Lee ([email protected]) or Ana Li ([email protected]). Emmy Yi is a marketing specialist at SEMI Taiwan.