4 Key Trends Powering EDA Adoption in 2021 & Beyond

The growth of the electronic design automation market is a key driving force for many industries around the world. EDA consists of a combination of tools designed to design and verify electronic systems, integrated circuits (ICs), and printed circuit boards (PCBs). With 35 billion IoT devices expected to be installed worldwide by the end of 2021 (source credit: techjury.net), the demand for advanced electronic design automation software will be higher than ever before.

“The size of the electronic design automation industry could exceed USD 20 billion by 2027.”
Global Market Insights Inc..

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As the number of connected devices continues to grow globally, companies are finding themselves struggling with the ever-changing EDA market. Some of the recent trends featured Electronic design automation industry Listed below:

# 1 Growing demand from the medical community

The medical sector has for some time included the use of advanced technology, which has made it convenient to conduct treatments and surgeries that were once considered impossible. Endoscopic and laparoscopic surgery have become commonplace only with the help of electronic design automation tools. Companies build high-performance, AI-enabled devices for advanced diagnostic and medical procedures by installing electronic design automation software in the manufacturing process.

EDA is helping companies develop and design AI-enabled diagnostic devices that enable medical companies to advance cutting-edge AI technologies. EDA applications help improve IC design tools using machine-learning algorithms for faster results. Ibex Medical Analytics and KSM recently announced that they have begun using Galen ™ gastric, an-AI-enabled diagnostics and quality control solutions to detect gastrointestinal (GI) tract cancer – possibly due to the introduction of EDA at production levels.

# 2 The growing popularity of minimization

As the popular saying goes in the electronics industry – small new big. Minimization of large devices is a major factor that has allowed electronics to penetrate deeper into diverse industrial applications. Smaller, more compact, and more functional devices are considered useful, especially in the areas of automotive, medical, and consumer electronics.

The downside of electronic devices has led to the evolution of thin mobile phones, tablets, laptops, wearables and nano-sized, sophisticated surgical instruments for medical professionals. As the trend of maintaining traction continues, the demand for EDA tools will continue to grow.

Researchers at Northwestern Engineering recently created a flying microchip / microflier – the smallest man-made flying structure. It is embedded with very small technologies like antennas, sensors, routers etc. and can be used to monitor air pollution and airborne diseases. Minimization has been made possible by advances in electronic design automation software and their impact on the final semiconductor chip design.

# 3 The demand for advanced technology in production is increasing

The advent of robotics and automation in the manufacturing sector is not new. Today, robots have been deployed in production for activities such as pick and place, physical testing, packaging, semiconductor production, soldering, and more. Electronics manufacturing is becoming increasingly complex as minimization becomes more effective, requiring precise replacement and flawless design. The demand for EDA software has become even more important as it is used to ensure that all steps in the electronics manufacturing cycle – such as material handling, assembly lines and testing – are performed seamlessly.

As can be imagined as a breakthrough, Synopsys, Electronic Design Automation (EDA) and semiconductor IP, and TSMC recently joined hands in an advanced design capability agreement. Through this partnership, TSMC will be able to take advantage of Synopsys’ huge EDA solution portfolio for the latest versions of 3 nanometer (nm) process technology DRM and SPICE models for use across mobile, 5G, and AI applications.

# 4 Transfer to an online platform

With digitalisation becoming mainstream, EDA vendors are now shifting to online platforms to optimize their workflow. Typically, semiconductor companies use on-premise data centers to verify semiconductor designs. However, the EDA workflow is complex and includes design, simulation, verification, and more for chip production. To reduce costs, balance schedules and avoid the use of valuable data center resources, it is practical to transfer EDA workloads to the cloud, which boasts of high-performance computing infrastructure that will help scale the number of simulations.

A few months ago, Arm announced that it plans to shift its EDA workload to AW, including design validity at the production level. With this move, Semiconductor will be able to scale its computing storage and power and storage much faster and at lower cost as opposed to purchasing aggregate servers and other software. According to the company, shifting EDA workloads to the cloud during the manufacturing phase is a first step for the semiconductor industry – a move that will make a big difference in the market, as it helps reduce costs, schedule risks and increase throughput.

Electronic design automation companies work to create advanced equipment, platforms and software products to reduce the costs associated with testing, simulation and verification of semiconductor chips before actual production. EDA tools are also installed to optimize and prepare the chip layout ready for production. Currently, despite the challenges, EDA is at the center of industry innovation and will continue to pioneer important innovation in the future.

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