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The highly anticipated 18th International Microsystems, Packaging, Assembly, and Circuits Technology Conference, also known as IMPACT 2023, took place with grandeur from October 25th to 27th at Hall 1 of Taipei Nangang Exhibition Center. This prestigious event was co-organized by leading institutions in the fields of electronics, including IEEE Electronics Packaging Society (IEEE EPS) – Taipei, International Microelectronics Assembly and Packaging Society (iMAPS) – Taiwan, Industrial Technology Research Institute (ITRI), and the Taiwan Printed Circuit Association (TPCA). Under the overarching theme of “IMPACT on the Future of HPC, AI, and Metaverse,” the conference delved deep into the realm of cutting-edge IC packaging and circuit board technologies that are specifically tailored for next-generation applications in HPC, AI, and the Metaverse.
At the opening ceremony, Dr. Wei-Chung Lo, the Chair of IMPACT 2023, President of iMAPS – Taiwan, and Deputy Director of the Electronic and Optoelectronic System Research Laboratories at the ITRI, noted that the event had attracted over 700 participants, with nearly 30% from overseas. This made IMPACT 2023 the largest industry event for advanced semiconductor packaging technologies in Asia. Dr. Lo expressed gratitude for the support from the IEEE EPS, iMAPS, International Electronics Manufacturing Initiative (iNEMI), and Japanese associates including the International Conference on Electronic Packaging (ICEP) and Japan Institute of Electronics Packaging (JIEP). He also thanked the tremendous support from individuals and organizations across the industry and academia.
Innovations in Critical 3D Packaging Technologies and System-Level Performance Upgrade Will Trigger a Surge of New AI Applications
Following the opening ceremony, plenary speeches were delivered by Dr. Jun He, Vice President of Quality and Reliability and Operations and Advanced Packaging Technology and Service at TSMC, and Dr. Raja Swaminathan, Corporate Vice President at AMD. During his speech, Dr. He emphasized the explosive growth in the 3D packaging technology market, with a projected global market value exceeding USD 100 billion by 2025. Dr. He also highlighted TSMC’s proactive approach in aggressively promoting its “3DFabric” platform, which combines advanced packaging technologies such as SoIC (3D), CoWoS (2.5D), and InFO (2.5D). As a testament to the power of 3D packaging technology, he pointed out that NVIDIA’s latest generation GPU (i.e., the H100) has achieved a remarkable six-fold performance improvement compared to its predecessor (i.e., the A100).
The strong demand for HPC is fueling the extensive commercial adoption of 3D packaging technology. In light of this trend, TSMC plans to expand its cleanroom space for the 3D packaging process, with expectations of more than doubling it by 2025. Furthermore, TSMC is expediting collaborations with ecosystem partners to advance critical 3D packaging innovations. One example is hybrid bonding, which enhances interconnect density. Another example is key innovations in 3D packaging that optimize signal integrity for HBM.
Dr. Swaminathan, Corporate Vice President of AMD, said that the demand for supercomputers and AI performance had previously been growing exponentially, doubling every 1.2 years. However, the growth rate has become even higher recently, doubling within a year. The industry’s primary focus lies in upgrading system-level performance through innovations in high-speed interfaces, advanced packaging, and heterogeneous integration. AMD, in particular, is directing its attention toward improving inter-chip communication and energy efficiency. Leveraging its evolving 3D stacking technology and hybrid bonding packaging, AMD aims to substantially reduce power consumption in inter-chip communication. AMD anticipates that it will achieve a 30-fold increase in HPC and AI training efficiency per watt over the next five years.
In summary, TSMC and AMD, as respective leaders in foundry services and IC design, are focusing on the synergistic relationship between advanced packaging technologies and next-generation AI architectures. They recognize that these two sets of technologies work together to drive substantial improvements in the computing capabilities of semiconductor chips.
Collaborative Design to Spark Major Transformations in AI, and High-Density Heterogeneous Integration Platform to Become Crucial Bridge to Future of Semiconductor Technology
This year’s conference marked the third edition of the IEEE EPS Panel Discussion / Forum, presided over by Dr. C. P. Hung, Vice President of the ASE Group. As a key organizer of the IMPACT conference, the IEEE EPS once again brought together the latest R&D findings and influential speakers to facilitate the exchange of information regarding the most recent trends and technological advancements within the semiconductor and electronics industries.
The inception of the IEEE EPS Panel Discussion has seen a progression of significant themes. The first edition centered on the realm of 5G, followed by the second edition that explored edge computing. Notably, this year’s panel was jointly organized with the IEEE Council on Electronic Design Automation (CEDA). The primary focus of this year’s panel discussion – also known as the IEEE EPS and CEDA Joint Panel – was on ECAD tools capable of optimizing the collaborative design process for chips, packages, and systems.
The idea to join forces with the IEEE CEDA originated from Dr. Bill Chen, Fellow and Senior Technical Advisor at the ASE Group. Delivering his remarks remotely from a different location, Dr. Chen emphasized that although AI and machine learning are still in their nascent stages, significant transformations are anticipated over the next few decades. Dr. Chen stressed that collaborative design will drive the development of AI-related products and applications. This trajectory of development will also necessitate the establishment of an open-source chip ecosystem and standardized interfaces to continuously improve efficiency.
In addition, the IEEE EPS and CEDA Joint Panel specially invited renowned scholars and experts from domestic and international backgrounds. Prominent speakers include Dr. Madhavan Swaminathan, Head of the Department of Electrical Engineering at Pennsylvania State University; Dr. Chih-ming Hung, MediaTek’s Assistant Vice President of Technology; Dr. Arvind Sundarranjan, Managing Director at the Applied Packaging Development Center (APDC); Dr. Kyu Lim Sung, Professor at the Georgia Institute of Technology; Dr. Debendra Das Sharma, Intel’s Senior Fellow; and Nan Wang, Vice President of Component Quality and Technology at Cisco.
Dr. Madhavan Swaminathan stressed that high-density heterogeneous integration platforms will be a future trend. Moreover, such platforms have to incorporate a wide range of technologies from antennas to AI to support applications related to network communication and edge computing. This means that R&D and collaborative design also have to take place simultaneously across various fields, with distributed computing and telecommunication solutions playing crucial roles. On the topic of AI-assisted design, Dr. Hung from MediaTek discussed the importance of synergy among material technology, mechanical engineering, EDA tools, etc. However, Dr. Hung also noted that not all advances in these fields have immediate practical uses in the development of AI applications. In the case of 3D AI machine learning, the maturity of the tools for training needs to be considered.
Turning to the topic of hybrid bonding, Dr. Madhavan Swaminathan pointed out that it is a key technology in advancing AI and HPC, as it brings about computing solutions that can handle massive amounts of data with reduced latency and greater power efficiency. On the other hand, hybrid bonding is a highly complex manufacturing process that involves at least hundreds of steps. Optimizing individual steps one at a time is not enough; synergistic progress has to take place across numerous sections of the process in order to raise the yield rate.
Dr. Sung believes that initiating the next wave of the “AI revolution” will require collaborations among various types of chips, and EDA tools provide the necessary support for the development of 2.5D and 3D packages. Besides being the indispensable assistant for chip designers, EDA tools can also contribute to decision-making regarding materials and bonding methods.
As for how the UCIe standard can contribute to the expansion of the ecosystem for small-sized chips, Dr. Debendra Das Sharma said that UCIe allows for the mixing and matching of multiple chips at the package level to overcome manufacturing limitations and increase yield rates. Currently supporting 2D and 2.5D packages, UCIe will also be introduced to 3D packages in the future. When building SoCs, this standard enables innovations at the package level, integrating not only CPU, GPU, and memory but also supporting interfaces such as USB, PCIe, and CXL. The adoption of UCIe is expected to result in dynamic and configurable systems.
Likewise, when discussing the topic of heterogeneous integration, Cisco’s Vice President Wang, mentioned Open Platform Communications (OPC), a set of standards and specifications for industrial telecommunication. Wang said that co-packaged optics, which falls under OPC, can effectively address the challenges related to power consumption and costs associated with the increasing demand from machine learning networks for high-speed connectivity and high-volume computing capability. With OPC technologies, optical components can be closely integrated with Ethernet switch ICs and packaged on the same substrate, thereby reducing system power consumption by as much as 30%. However, the adoption of OPC will bring new challenges related to the integrity of signals and power supply. Hence, collaborative design and system-level optimization are necessary to achieve large-scale application.
Seeking the Best Collaborative Design Tools to Rapidly Address the Needs in the Market for Heterogeneous Integration Solutions
In the second half of the joint panel, Dr. Yao-wen Chang, Dean of the College of Electrical Engineering and Computer Science at National Taiwan University, took over as the moderator. He raised three questions for the experts to discuss and share their insights. The first question he posed was, “How can AI and advanced packaging technologies address the most challenging issues in the development of applications related to AI and edge computing?” Dr. Swaminathan from Penn State was the first to respond, explaining that AI requires large-scale computing and thus requires cooperation among chips made with different process nodes. This also means that advanced packaging technologies can facilitate the integration of various types of chips, including RF chips, GPUs, CPUs, and even optical components.
Dr. Hung from MediaTek cited successful cases of AI being applied to power supply analysis and chip layout optimization. However, the bottleneck in advancing 3D integration lies in the lack of data, so AI cannot fully replace humans in designing chips at the present moment. Dr. Sung also pointed to insufficient data related to circuit designs. This impose limitations in supervised learning. Currently, the academic community is ramping up research efforts in unsupervised learning and reinforcement learning. Cisco’s Vice President Wang said heterogeneous integration could address certain challenges in the development of network systems, but he also acknowledged that chip design and chip manufacturing could become more complex as a result.
The second question was, “What are the key technological challenges that we must overcome when the next generation of AI interacts with human intelligence? And when can we expect to see solutions to these challenges?” In response to this question, Dr. Das Sharma said that heterogeneous integration can combine processors and memory in a single package, while 3D stacking can further narrow the distance of inter-chip communication, thereby leading to a faster data transfer rate, better performance, and less power consumption. Dr. Sundarrajan also pointed out that solving the challenges of heterogeneous integration will necessitate technological innovations in materials and other areas. Reducing the space between the chip and the substrate, lowering the defect rate, finding ways to strengthen the bond between different materials, and eliminating chip warping are some of the issues mentioned in the joint panel. These kinds of solutions are required to enable chips to achieve the most optimal performance.
The final question posed by Dr. Chang was, “Regarding EDA tools, what is the extent of their readiness for advanced packaging? And what are the major technological gaps that require immediate attention?” In answering this question, Dr. Sung said that the development of EDA tools is somewhat lagging behind when it comes to heterogeneous integration and the construction of 2.5D and 3D packages. Overall, chip designers need more functionality and automation from their EDA tools. While tools for 2D packages are quite mature, there is still considerable room for improvement in designing chips featuring 3D integration. Dr. Madhavan Swaminathan added that current providers of EDA tools tend to be too passive. They are reluctant to invest in new technologies without specific orders from customers. Swaminathan believes EDA companies need to partner with other technology developers to push forward heterogeneous integration.
Dr. Hung stated that even for 2D packages, chip design companies need to have their own in-house tools to address the shortcomings of commercial EDA tools from external providers. Dr. Hung believes EDA companies should respond more promptly to the needs of IC design houses. Turning to Dr. Das Sharma, he stated that when EDA companies see market potential, they will invest in new technologies. The key is to make them recognize that the aforementioned technologies represent the next major direction in the evolution of chip designs. Lastly, Cisco’s Wang called attention to the different integration and analytical capabilities that EDA tools and systems have to have in order to prepare for the potential issues that may arise in the future development of heterogeneous integration. Early preparations are essential.
As a collaborative effort between its organizers and a consortium of partnering entities, IMPACT 2023 unfolded as a massive three-day convention, featuring 33 sessions comprising seminars, panel discussions, lectures, and more. The event not only included keynote presentations by top executives from companies like TSMC and AMD but also assembled hundreds of heavyweight experts from academia and accomplished professionals from various industries worldwide. Additionally, the IEEE EPS and CEDAS Joint Panel was held for the first time, offering attendees an in-depth look into the realm of AI-based collaborative design. Embracing a holistic approach, IMPACT 2023 transcended mere technological discourse to explore the contours of market trends, igniting the sparks of innovation that promise to shape our future.
It is worth noting that TPCA Show 2023 was held concurrently, featuring 1,386 booths set up by companies around the world. More than 480 international brands were showcasing their products and services at this event. In terms of thematic focus, the exhibitions at TPCA Show 2023 were primarily about semiconductors (i.e., chip assembly and packaging), net-zero emissions, smart manufacturing, and forward-looking solutions. The organizers of TPCA Show 2023 were eager to provide a wide range of services to foreign visitors as they sought to make the event the premier international platform for presenting the latest innovations and trading cutting-edge solutions. Like IMPACT, TPCA Show aims to promote the development of various industries. These events also continue to demonstrate Taiwan’s capabilities in the areas of PCBs, semiconductors, electronics, etc.
(The featured image of this article shows Dr. Wei-chung Lo delivering the opening remarks on the first day of IMPACT 2023. Dr. Lo is the Chair of IMPACT 2023, President of iMAPS – Taiwan, and Deputy Director of the Electronic and Optoelectronic System Research Laboratories at ITRI. Source: IMPACT.)
News
The AI landscape witnesses a robust surge with the consecutive launches of AMD’s “Instinct MI300” series AI chips and NVIDIA’s upcoming “B100” GPU structure. This wave of innovation propels a flourishing demand for AI-related Outsourced Semiconductor Assembly And Test Services (OSAT), surpassing initial estimates by over 10%. OSAT companies like ASE Holdings, King Yuan Electronics (KYEC), and Sigurd are poised to experience a notable uptick in revenue, as reported by UDN News.
According to reports, AMD is launching the “Instinct MI300” series AI chips this week, and NVIDIA plans to unveil the next-gen “B100” GPU next year. This successive release of new AI products by the two giants is boosting momentum in related OSATs collaboration.
NVIDIA is gearing up for the 2024 launch of its next-gen Blackwell architecture B100 GPU, saying AI performance exceeding twice that of the H200 GPU under the Hopper architecture, signifying a substantial leap in computational prowess.
Positive Outlook in 2024 for OSATs Amid AI Chip Development
Industry source indicates that due to the AI extensive computation requirements, advanced packaging is gradually becoming mainstream. This involves stacking chips and packaging them on a substrate. Depending on the arrangement, it is divided into 2.5D and 3D packaging. The advantage of this packaging technology is the ability to reduce chip space while also reducing power consumption and costs.
It is said the surge in AI chip orders from AMD and NVIDIA has led to a bottleneck in TSMC CoWoS advanced packaging capacity. This unexpected demand has exceeded projections for related OSATs, including ASE Holdings, KYEC, and Sigurd.
In the case of ASE Holdings, its subsidiary Siliconware Precision Industries (SPIL) possesses the advanced packaging capacity essential for generative AI chips. Joseph Tung, CFO of ASE Holdings, notes that while AI currently in its early-stage and is set to drive explosive growth. As AI integrates into existing and new applications, the demand for advanced packaging is expected to fuel the industry’s entry into the next super growth cycle.
For KYEC, a significant expansion in AI chip testing capacity since Q2 this year positions the company to benefit from the surge in demand.
Sigurd’s COO Tsan-Lien Yeh addresses that, with the release of AI phones, recognizing the doubled testing time for phone chips, which now carry APU/NPU for AI computing compared to general 5G chips. Sigurd has upgraded its equipment to align with future customer needs.
(Image: ASE VIPack’s video)
News
India could see at least three more semiconductor fabrication units coming up in the next few months with cumulative investments to the tune of USD 8-12 billion, Union Minister for Electronics and Information Technology Ashwini Vaishnaw said on Tuesday.
India is working hard to get big semiconductor companies to build chip plants in the country with its $10 billion semiconductor program. Global semiconductor giants are considering making factories in India driven by the need to diversify supply chains beyond China and the big demand for tech talents in India.
According to Deccan Herald’s report. At the unveiling of AMD’s global design center in Bengaluru on November 28th, Ashwini Vaishnaw, Union Cabinet Minister for Railways, Telecommunications, Electronics and Information Technology of India, briefed journalists on ongoing negotiations with several local governments to determine precise locations in the following months.
AMD’s global design center plans to host around 3,000 AMD engineers in the coming years, focused on the design and development of semiconductor technology including 3D stacking, artificial intelligence, machine learning, and more. Vaishnaw pointed out that AMD setting up its biggest design center is strong evidence of how much global companies trust India. Besides, Vaishnaw highlighted the achievement of Micron’s semiconductor plant project, which was revealed in June and started construction in September. He said the success of Micron’s initial facility in India has boosted confidence globally.
Apart from global giants’ investment in India, the minister also told about the Semiconductor Lab (SCL) progress in Mohali, mentioned significant headway in the Expression of Interest (EoI) process. He anticipates finalizing matters within the next 5-6 months. The lab is planned to serve as both a research and semi-commercial facility.
Empowering India’s Semiconductor Dominance
The Indian government asserts that a comprehensive microprocessor chip manufacturing initiative is on the horizon in the country. Anil Agarwal, Chairman of Vedanta, anticipates the launch of “Vedanta chips made in India” by 2025, reported by icbank on weixin.
The government envisions establishing a “semiconductor city” in Dholera, Gujarat, covering an area equivalent to Singapore, with Prime Minister Modi expressing confidence in attracting both domestic and international giants to set up manufacturing plants despite the remote location.
The tech hub in Bangalore has played a pivotal role in India’s ascent as a global participant in the semiconductor network, primarily through chip design. Over the past two years, substantial government subsidies have transformed India into a hub for electronic product manufacturing.
India’s Challenges abound in the Actual Chips Manufacture
Despite initiatives like the “production-linked incentive measures” encouraging mobile assembly in India since 2020, chip manufacturing remains a formidable task.
Presently, nearly all cutting-edge chips are produced in Taiwan, with China’s chip investments surpassing those of India. Vedanta Group’s Agarwal plans to kickstart chip manufacturing within two and a half years, extending invitations to global chip manufacturing experts.
While today’s cutting-edge chips are predominantly manufactured in Taiwan, TSMC has even established a fab in Arizona with the assistance of the U.S. “Chip Act.”
India lacks a historical presence in chip manufacturing and faces a shortage of highly skilled engineers and equipment. Nevertheless, the government aims to achieve what companies like TSMC took decades to accomplish through substantial spending and capital investment promotion. However, China’s significant investments in domestic chip manufacturers, following the U.S. ban tightening China’s semiconductor development last October, far exceed India’s investments in local companies.
With the goal of establishing India’s inaugural semiconductor foundry, Mr. Agarwal of Vedanta Group aims to commence chip manufacturing within two and a half years, extending invitations to international talents like David Reed and Texas Instruments.
Agarwal aspires to attract around 300 foreign experts from East Asia and Europe to Gujarat. The manufacturing of microchips also necessitates a significant amount of customized infrastructure, with Vrishno, the responsible official, indicating that India’s largest chemical plant near Dholera can produce the specialized gases and liquids required for any chip factory’s operation.
(Image: AMD India)
News
According to TechNews’ report, during a recent financial conference, Samsung revealed its plans to diversify its sales structure by expanding its clientele in the fields of artificial intelligence semiconductors and automotive, moving away from its previous heavy reliance on the mobile sector.
As of 2023, it is understood that Samsung’s foundry sales distribution includes 54% from mobile, 19% from high-performance computing, and 11% from automotive.
According to a report from Wccftech, senior executives at Samsung have indicated that major players such as super-scale data centers, automotive original equipment manufacturers (OEMs), and other clients have been in contact with Samsung, considering the adoption of Samsung’s foundry services to manufacture their designed chips.
This includes the in-development 4-nanometer artificial intelligence accelerator and the 5-nanometer chips for the top-ranked electric vehicle company. Currently, Samsung is gearing up with its advanced packaging solution called SAINT (Samsung Advanced Interconnection Technology), aiming to compete with TSMC’s advanced packaging, CoWoS. Based on information disclosed by Samsung, there might be a collaboration with AMD in the field of artificial intelligence, involving the manufacturing of certain chips.
In fact, recent rumors suggest that Samsung has already reached an agreement with AMD to provide HBM3 and packaging technology for the upcoming Instinct MI300 series. Additionally, AMD might adopt a dual-sourcing strategy for the Zen 5 series architecture, choosing TSMC’s 3-nanometer process and Samsung’s 4-nanometer process technology for manufacturing the next-generation chips.
According to sources, besides the artificial intelligence domain, Samsung is likely to have received orders from the electric vehicle giant Tesla. The speculation points towards the possibility of fulfilling orders for Tesla’s next-generation HW 5.0 chip, designed for fully autonomous driving applications.
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(Photo credit: Samsung)
News
According to TechNews’ report, there are recent rumors indicating that AMD’s next-generation chip, with the Zen5C architecture codenamed “Prometheus,” will adopt a “Dual Foundry Mode.” This means it will simultaneously utilize TSMC’s 3nm and Samsung’s 4nm processes. This move suggests that AMD aims to diversify chip manufacturing, avoiding reliance solely on TSMC for its upcoming products.
Industry sources suggest that factors such as geopolitical considerations, negotiation tactics, and the overall semiconductor manufacturing ecosystem drive the search for secondary sources. AMD’s decision to employ a dual foundry approach is likely a strategic move to mitigate risks in this dynamic landscape.
Reportedly, Samsung’s 4nm process will primarily be utilized for the base version of Prometheus, while TSMC’s 3nm process will be employed for the high-end variant of Prometheus.
EXTREMETECH finds AMD’s move intriguing, speculating that it might stem from uncertainty about sourcing all chips exclusively from TSMC. This is significant for Samsung, historically excluded from the consumer tech and gaming sector. Since NVIDIA switched from Samsung to TSMC for the production of Ampere GPUs using the 8nm process, Samsung has been left out of the equation.
If the collaboration between AMD and Samsung proves successful, other companies may also consider shifting to Samsung. Reports suggest that AMD’s choice of Samsung’s 4nm process over the 3nm process could be attributed to potential yield challenges.
While it’s uncertain whether AMD will indeed implement the “Dual Foundry Mode,” the anticipation for the Zen5 architecture next year is high. Samsung is currently ahead of the industry in the adoption of GAA (Gate-All-Around) technology for its manufacturing processes, introducing GAA technology with their 3nm process ahead of others in the industry. TSMC, on the other hand, is anticipated making a similar change no earlier than 2025.
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(Photo credit: AMD)