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VP, R&D, AI/ML Digital and Signoff, Cadence

To enable the semiconductor industry to continue growing, the chip design process must become more efficient. With the availability of massive, cloudenabled, distributed computing and advancements in ML computer science, the next chip design automation revolution is now possible states Venkat Thanvantri | VP, R&D, AI/ML Digital and Signoff | Cadence while talking in an exclusive Interview with Niloy. In this most-awaited interview, the veteran underlines what’s changing design processes for the semiconductor industry and also the need for advanced technologies like AI/ML in their respective design strategies. Edited excerpts below.

Cadence’s Cerebrus Intelligent Chip Explorer utilizes massively distributed compute power and a unique machine learning (ML)-based reinforcement learning engine, combined with the Cadence digital full flow solution, to deliver better PPA more quickly. Cerebrus automation capabilities enable engineering teams to scale more efficiently and boost productivity so more designs can be implemented concurrently. In addition to automated implementation flow optimization, Cerebrus has the capability to explore high-level design optimizations, such as dynamically resizing and shaping a floorplan to improve PPA much more efficiently than a manual approach. All design learnings are stored in a reinforcement learning model that can easily be used in future design projects to optimize the flow even more quickly. Cerebrus offers a revolution in chip design productivity, which will allow the semiconductor industry to continue growing and delivering the new SoC product features and capabilities we all expect in our increasingly connected world.

To enable the semiconductor industry to continue growing, the chip design process must become more efficient. With the availability of massive, cloudenabled, distributed computing and advancements in ML computer science, the next chip design automation revolution is now possible. The Cadence Cerebrus Intelligent Chip Explorer utilizes both of these technologies, based on the industry-leading Cadence digital full flow, to deliver better power, performance, and area (PPA) more quickly. Engineering teams now are able to scale and become more productive using the Cerebrus reinforcement learning engine to meet the challenges of increasingly large and more complex system-on-chip (SoC) designs.

When Cadence talks about AI and ML in its software, we are talking about helping chip designers automate certain parts of the design process to speed time to market. The chip shortage has to do with manufacturing and

has largely been attributed to a supply and demand gap, which is outside our domain.

The pressure on chip production is due to the increase in the demand for electronics – not just in India but across the world, and not just because of an increase in demand in the 5G and Industry 4.0 verticals, but also in other verticals such as automotive, hyperscale computing, Internet of Things (IoT), medical, aerospace, to name just a few.

Cadence’s Cerebrus Intelligent Chip Explorer is built on massive compute and machine learning architectures and utilizes the complete Cadence digital full flow solution. Cerebrus uses a unique reinforcement learning engine to deliver better design PPA results. By using a completely automated, machine learning-driven, RTL-to-GDS full-flow optimization technology, Cerebrus can deliver better PPA results more quickly than a manually-tuned flow, thereby improving engineering team productivity. Cerebrus uses the latest scalable distributed computing technology resources, either on-premises or in the cloud, to enable efficient and scalable chip implementation for the ever-increasing size and complexity of current SoC designs.

Power, performance and area go hand-in-hand. That’s why the there is a dedicated acronym for it—“PPA”. It all boils down to the consistently increasing design complexity and size that we have seen in chips over the last decade or more. Chip designers are trying to optimize more and more functionality into a decreasing footprint. Change the area, and the power changes. Increase the performance, and the area and power change. Attempt to minimize power, and the area goes down—or up—depending on the optimization.

As chips scale in size and complexity, the interdependence of power, performance and area will only increase. All three are important considerations in chip design, with designers having to make tradeoffs between the three to optimize the chip.

We are seeing the following trends in the electronics industry today. - The Chip design industry is experiencing a renaissance. There is strong growth in 5G, autonomous driving, hyperscale compute, industrial IoT and other areas, which are underpinned with the application of artificial intelligence (AI) and ML. - New applications and technological interdependencies are generating demand for even more compute, more functionality, faster data transmission speeds. Today’s electronics have more chips in them with no end to this trend in sight. - As a result, next-generation chips must be produced faster and smarter. Engineers are overloaded and need support to keep up with demand. That is where ML in EDA comes into the picture. In terms of semiconductor design, these trends are having impact on: - Traditional chip and package design EDA: Electronics technology is proliferating to new, creative applications and appearing in our everyday lives. To compete, systems companies are increasingly designing their own semiconductor chips, and semiconductor companies are delivering software stacks to enable substantial differentiation of their products. Design size and complexity are increasing, with more designs on advanced process nodes. Other trends include 3D-IC and design for high-speed analog signals. - The system beyond the chip: Optimizing semiconductor devices for their targeted applications started in mobile devices and is now moving into cloud computing, automotive and other areas. Each application has different environmental conditions and constraints, requiring optimization of the silicon performance in the context of the system, as well as the system itself, across the boundaries of hardware and software, analog and digital, electrical, and mechanical. - Intelligence throughout: Many companies are introducing intelligent computation in their systems, which is creating a confluence of semiconductor design, system design and intelligent system design. To power the technologies and products of the future, the world’s most creative companies require end-to-end solutions across chips, IP, packages, PCBs and systems to meet demanding design requirements and deliver extraordinary products. Cadence has evolved to address these changes and formulated its “Intelligent System Design” strategy in which it delivers world-class computational software capabilities across all aspects of electronics system design.

The complexity of integrated circuits (ICs) means the number of possible design iterations that need to be evaluated continues to increase, but their regularity means design rules that work well can have a massive positive impact across large parts of the design. Using AI and ML to move from ‘maybe’ to ‘definitely’ in fewer iterative steps can deliver greater productivity in an automated flow. The industry is in a constant state of development to expedite the design process. As fabrication processes shrink in dimensions, the ICs become commensurately more complex, and, as any design engineer appreciates, complexity increases the design cycle. That is true for any type of design. Designers are spending an enormous amount of time performing multiple tasks—for example, finding the best PPA and developing the optimal floorplan. To really shorten the design cycle, ML is paramount, providing the best path forward when it comes to improving productivity and design success.

VP & Country GM – Secure Power, Schneider Electric India & SAARC

The intersection of hybrid cloud, server virtualization, artificial intelligence (AI) and transformational technologies at the edge are giving rise to the characteristic and projected growth of data centers across the country. The current situation has catalysed the need for increased network security, managing highly efficient workflows, processing massive volumes of data while rendering seamless interoperability, optimal growth and usage of decentralised cloud services. As data centers are evolving with new and emerging technologies that emphasize on sustainability and decarbonisation, some key trends that data centers will encompass going forward include:

• Intelligent Monitoring: Intelligent Monitoring empowers the crux of data center operations. The movement towards automating management and monitoring and in turn receiving real-time data and insights will transform the operational capacities across data centers. By harnessing the power of the Internet of Things (IoT) and analytics, intelligent monitoring will enable in breaking down silos across the infrastructure platform and increase visibility, transparency and bandwidth. This will further accelerate processes, improve uptime, predict needs and secure information with utmost reliability. • Hyperscale Data Centers: With increasing business demands and the growing pace of data consumption across industries, hyperscale data centers will be taking shape and pivoting existing operations significantly. The shift from on-premises to cloud and colocation providers has been driven by digital transformation. Increasing data center capabilities will be leveraged through hyperscale cloud giving enterprises the impetus to invest in scalable applications and solutions that render immense benefit. Hyperscale data centers will stay ahead of the curve in deploying smart, self-reliant and sophisticated solutions that reduce human intervention by integrating automation.

• Green Data Centers: Data centers of the future need to emphasize on energy efficiency and examine their impact on the environment. Along with powering sustainable and versatile solutions at the edge, green data centers will enable more cost-efficiency, reduce downtime and optimize the use of resources that sustain data center operations. Data centers of the future are being revamped to incorporate fundamental changes in their design and build to create more resilience and mitigate factors that could affect the ecosystem.