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The Executive Forum at SEMICON Europa in Munich on November 16 was a welcome opportunity to demonstrate the strategic importance of our vital industry.Executives across the entire electronics and applications value chain rightly pointed out the contribution that the semiconductor supply chain made to supporting the efforts to control COVID-19, which sparked explosive demand for semiconductors and led to the chip shortage and supply chain disruptions. The pandemic has heightened the urgency to establish the manufacturing capacity needed to support the global recovery and onward rapid growth of the semiconductor industry, which is projected to exceed $1.2 trillion in revenue by 2030.Semiconductors are the heartbeat of the way we work and live, and their vital importance is now recognized by governments worldwide including European Commission officials, as well as by the wider population.So far, so good. However the rapid industry growth brings opportunities and challenges. If we continue on the path we are now on, there will simply not be enough energy in the world to feed our data appetite in the so-called 5th wave of digital expansion. Many speakers at SEMICON Europa referred to the importance of sustainability and diverse skills, and many companies have put in place comprehensive programmes that will enable industry growth and lead toward net zero carbon emissions. The semiconductor industry is central to efforts to control climate change. Collaboration and cooperation across the European microelectronics ecosystem are essential.Europe is a world leader, and many stunning advances in technology have resulted from many collaborative projects, large and small, over the years. Many of the executives at SEMICON Europa stressed that these efforts must continue, and indeed be expanded, across the entire electronics and applications value chain. However, the focus remains on ever more capable technologies to match the needs of the digital age: data management, communications, computing capability and improving important application areas such as healthcare.(Clockwise) Laith Altimime, president of SEMI Europe; Luc Van den hove, president and CEO of imec; and Lars Reger, Executive VP and CTO of NXP Semiconductors present at SEMICON Europa 2021. But where are the programmes to drastically reduce carbon emissions and air pollution, eliminating the use of scarce resources and acting as a catalyst to keep 1.5 alive? SEMI is doing its part by establishing a sustainability initiative. To help the industry building the talent pipeline crucial to its future growth, SEMI has also developed workforce diversity programs. Both initiatives are bringing together leaders from across the semiconductor supply chain to address these critical challenges. These changes require major disruptions. Time and again, our industry has demonstrated that it can overcome tremendous challenge.Of course, many chip companies are already devoting significant time and effort to help meet the moment, and projects are underway across our industry focused on these great causes. Yet, we can’t rely on individual efforts to fix these global problems. Our industry, with so much capability and history of rapid innovation, needs to take the lead in changing the way we meet these industrial and social imperatives.Contact [email protected] to learn more about the SEMI Environmental, Health, Safety Sustainability initiative and help the semiconductor industry take action today.Learn more about SEMI Diversity and Workforce Development initiatives.Peter Connock is Chair of SEMI Europe Industry Strategy Symposium Committee and Chairman of memsstar Limited.Serena Brischetto is senior manager of Marketing and Digital Engagement at SEMI Europe.
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While Artificial Intelligence (AI) emerged in the 1950s, only in recent years have AI applications proliferated with the explosion of data and continuing improvements in Moore’s law that have driven rising processing speeds. Voice assistants, image analysis software, search engines, and speech and facial recognition systems were among the first applications to use AI. Today, adoption has spread to sectors such as agriculture, cybersecurity, healthcare, software development, e-government and the intelligent enterprise to generate jobs and help spur economic growth. The Edge AI Opportunity and the Microelectronics IndustryAI can be embedded in hardware devices such as advanced robots, autonomous cars, drones or Internet of Things (IoT) applications. Today, according to the EU’s digital strategy, data centres and other centralized computing facilities account for the vast majority – 80% – of AI data processing and analysis, with smart connected objects such as automobiles, home appliances and manufacturing robots that bring the compute function closer to the user representing 20%. The latter, known as Edge AI applications, are powered by edge-based machine learning chipsets, not the AI chipsets designed to run cloud-based machine learning algorithms.The EU’s white paper on AI published in February 2020 anticipates that the way data are stored and processed for AI applications will change significantly over the coming five years as edge computing applications proliferate. Most AI applications need to connect with devices that collect data and manage data flows. When the applications connect with cloud infrastructures to train large volumes of data for a machine learning model, the interface devices often require hardware support. Edge AI can minimize data transport by processing data directly from local devices to accelerate data analysis and decision-making and make data transport or accelerator hardware unnecessary, critical in reducing power consumption and enhancing data security for applications such as autonomous driving. Over the past 40 years, the ICT sector has been continuously increasing greenhouse gas (GHG) emissions despite efforts to shift to renewable energy. Cloud-based AI applications require an ICT infrastructure for high-performance computing and high-speed connectivity. According to MIT Technology Review, data centres’ AI workloads could account for a tenth of the world’s electricity usage by 2025. a mass update of cloud-based AI applications may significantly increase energy consumption, unlike with Edge AI. This is why the strategy for developing Edge AI is well-aligned with the EU’s Green Deal objectives. Europe aspires to play a leadership role in Edge AI to strengthen the sector’s competitiveness and protect the European digital sovereignty. Europe’s strong industrial competencies in embedded systems and microcontrollers will help the region promote development of European domestic AI solutions for emerging high-value IoT applications in industrial processes such as Industry 4.0, Connected and Automated driving (CSA), smart cities, climate action, healthcare, and national defence and security. With this strong strategic position in technology, Europe is well-positioned to invest to become the leader in the Edge AI global market.Preparing the Workforce for the Microelectronics IndustryTo design and manufacture leading Edge AI chipsets, European education providers and industry will need to work closely together to train the current and future workforces. Within the framework of the METIS project, a four-year project co-funded by the European Commission through the Erasmus+ programme, SEMI and imec deployed experts in the field to survey and interview focus groups. The survey identified the following key focus areas for workforce development: 1. True Capability of AI and Data Science With AI’s heavy dependence on data, the workforce of the future must be trained in areas of data science including data integrity to ensure quality, unbiased sourcing, collection and accurate analysis necessary to interpret huge volumes of data. Europe also needs to train the next generation of AI chip designers in data security and privacy – key challenges to the widespread deployment of Edge AI chips. 2. Climate Change, Sustainable Development Goals (SDGs) and Social Inclusion TrainingSince the industry must be able to develop Edge AI solutions to enable the digital transformation while limiting GHG emissions, microelectronics engineers need to be schooled in climate change and understand how their work contributes to meeting the United Nation’s Sustainable Development Goals (SDGs). Workplace diversity and social inclusion are also important target areas for education since Edge AI applications should serve various groups of people with different needs.3. EthicsChip industry workers must also be educated in ethical issues of AI related to the technology’s potential societal impact in the near future[1]. With AI applications capable of monitoring Internet searches based on users’ personal preferences and biases to deliver tailored advertising, news and other information, developers must recognize how the technology can influence thinking and behaviour of individuals and groups. This awareness can help developers strike a balance between supporting commercial interests and societal good so the microelectronics industry can ensure ethical implementation of AI. 4. Cross-disciplinary Skills Required for AIAI development requires a comprehensive, cross-disciplinary skill-set to be able to integrate the work of specialists from diverse educational, cultural and professional backgrounds critical to developing non-biased AI solutions. For example, in addition to technical expertise, microelectronics AI developers must be able to communicate clearly and work in close-knit teams with non-technical experts from business, law, medicine and the social sciences.What’s Next?The microelectronics industry has a tremendous opportunity to develop new chip-based solutions for AI architectures, and apply AI techniques to improve operational efficiencies of design and manufacturing. To seize this opportunity, the industry must work closely with education providers to groom the next generation of skilled workers. This tight collaboration is critical to designing and delivering specialised courses to college and university students as well as engineers now working in the chip sector. The stakes are high. By preparing workers to develop Edge AI chipsets, the microelectronics industry can help the world confront some of the greatest challenges it faces today.For more information, see SEMI Responds to European Commission White Paper on Artificial Intelligence.METIS is a Sector Skills Alliance project co-funded by the European Commission’s Erasmus+ Program and coordinated by SEMI. The four year project, launched in November 2019, will develop a Microelectronics Skills Strategy. Based on the strategy, the METIS project will design 43 training modules for 1,100 hours learning in four key areas of the microelectronics sector.We thank Patrick Blouet (STMicroelectronics) and Jeroen Geusens (imec) for their valuable contributions to this article.[1] Ethics of Artificial Intelligence and Robotics, Stanford Encyclopedia of PhilosophyDr. Yanying Li is senior manager of Collaborative Projects at SEMI Europe.Dr. Pushkar P. Apte is the strategic technology advisor for the Smart Data AI Initiative at SEMI
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As the world combats climate change, the chip industry continues to build momentum in becoming a better steward of the environment. In July, Taiwan chip giant TSMC became the world’s first semiconductor company to join RE100, the global initiative to move away from a widespread reliance on fossil fuels and toward 100% renewable electricity. Applied Materials soon followed with a commitment to expand its renewable energy capacity. For the past four years, ASE Group, the largest outsourced semiconductor assembly and test (OSAT) provider, was named an industry leader in the Dow Jones Sustainability Indices (DJSI), making clear its commitment to protecting the environment. For its part, TEL was selected to be part of the FTSE4Good, a series of ethical investment stock market indices, and FTSE Blossom Japan, an index that gauges the performance of Japanese companies demonstrating strong Environmental, Social and Governance (ESG) practices.SEMI bolsters commitment to green energySEMI has also strengthened its commitment to promoting renewable energy in the semiconductor industry by adding the Green Power Pavilion at this year’s SEMICON Taiwan and continues to support the green energy movement as a co-organizer of Energy Taiwan. The largest renewable energy event in Taiwan, Energy Taiwan features international exhibitions, forums, policy initiatives and business matching events. This year the event attracted more than 12,000 visitors from 50 countries to highlight renewable energy breakthroughs and new products. The SEMI events complement RE100, which works across a wide range of industries that include financial services and retail. The initiative connects more than 260 members that count among them the world’s most influential businesses such as Apple, Google and Facebook and their suppliers through educational events.In many respects, TSMC is becoming a beacon of green energy in the chip industry. In July, the company committed to 20-year agreement to buy offshore wind power gear made by energy firm Ørsted in Taiwan, the global leader in the wind power industry. According to the purchase agreement, TSMC will offtake full production from 920-megawatt wind farms off the coast of Changhua County in western Taiwan expected to start operations in 2025 or 2026. The agreement will by far mark the world’s largest corporate green energy order in the semiconductor manufacturing and renewable energy industries and demonstrates TSMC’s long-term commitment to environmental sustainability.In addition to sourcing renewable energy, TSMC has been working closely with its downstream and upstream suppliers to help drive supply chain improvements geared toward a greener industry by offering on-site coaching, energy audits and educational resources. But the company's focus on energy efficiency is nothing new. For years, its Supply Chain Management forum has promoted industry sustainability and corporate responsibility. Moreover, TSMC worked with SEMI at this year’s SEMICON Taiwan to generate greater awareness of the importance of green energy to the industry and encourage SEMI members to become more involved in the movement.Supply chains expand eco-friendly practicesThe drive toward greener semiconductor manufacturing is also expanding to encompass entire supply chains. One notable initiative is Green Supply Chain Management (GrSCM), an effort to integrate environmental thinking into every level of the supply chain, from product concept to distribution. GrSCM involves the retooling of product design, materials sourcing, manufacturing and processes to reduce the ecological footprint of factories. So far, the results are encouraging. More companies are factoring environmental sustainability into their purchasing decisions to urge suppliers to better manage their power usage and join the green energy movement – an important step in curbing the unavoidable consequences of climate change. Terry Tsao is Global Chief Marketing Officer at SEMI and President of SEMI Taiwan.
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