Electronic Design Automation (EDA) for PCB and MCM Market

In this report, the Electronic Design Automation for PCB and MCM Market has been segmented by Product Type, Deployment Mode, Application, End-User, and Geography.

Electronic Design Automation for PCB and MCM Market, Segmentation by Product Type

The Electronic Design Automation Market has been segmented by Product Type into PCB Design Software, MCM Design Software, Simulation Tools, Verification Tools, and Others.

PCB Design Software

This segment holds a significant portion of the market due to the rising demand for compact and complex circuit designs in electronics. PCB design software is essential in industries like telecom, consumer electronics, and automotive. It is expected to maintain over 35% of the market share through 2031.

MCM Design Software

Multi-chip module (MCM) design tools are gaining popularity due to the demand for miniaturization and system integration. They enable efficient packaging of multiple ICs and are widely used in aerospace and defense electronics. This sub-segment accounts for nearly 20% of the market.

Simulation Tools

Simulation tools enable accurate modeling of electronic behaviors before manufacturing, reducing development time. With their role in enhancing design validation and performance optimization, this segment captures about 18% of the total market.

Verification Tools

Verification tools ensure logical consistency and error detection in circuit designs. Their importance in preventing design flaws and compliance issues has grown, contributing to over 15% market share.

Others

This segment includes niche tools catering to specific EDA requirements like layout editing, RTL analysis, and thermal modeling. While still emerging, these tools hold nearly 12% of the market as innovation continues to expand EDA functions.

Electronic Design Automation for PCB and MCM Market, Segmentation by Deployment Mode

The Electronic Design Automation Market has been segmented by Deployment Mode into On-Premises and Cloud.

On-Premises

On-premises deployment remains preferred by large enterprises for data security and customization. This model provides complete control over EDA tools and infrastructure, contributing approximately 58% to the market.

Cloud

The cloud-based segment is rapidly expanding with increasing adoption of SaaS EDA tools across startups and SMEs. Offering scalability, collaboration, and cost benefits, cloud deployment is expected to surpass 42% market share by 2031.

Electronic Design Automation for PCB and MCM Market, Segmentation by Application

The Electronic Design Automation Market has been segmented by Application into Networking & Communications, Automotive, Medical, Industrial, Instrumentation, Cellular Phone, Aerospace & Defense, Computing, Storage, Peripherals, and Others.

Networking & Communications

This segment leads due to heavy investments in 5G infrastructure and telecom equipment. High complexity in network chipsets drives demand for advanced EDA tools, contributing over 22% of the market.

Automotive

Automotive applications are growing due to increased use of semiconductors in EVs and ADAS systems. As vehicle electronics expand, this segment commands around 18% of the market.

Medical

Medical devices require precision and regulatory compliance, pushing demand for robust EDA tools. This segment holds about 10% of the market and is steadily expanding with digital health innovations.

Industrial

With the rise of Industry 4.0, industrial applications contribute significantly to the market, especially in automation, robotics, and smart factory electronics. This segment occupies around 13% market share.

Others

Additional applications like consumer electronics, computing, and peripherals round out the remaining 37%, reflecting the broad utility of EDA tools across sectors.

Electronic Design Automation for PCB and MCM Market, Segmentation by End-User

The Electronic Design Automation Market has been segmented by End-User into OEMs, EMS Providers, and Others.

OEMs

Original Equipment Manufacturers (OEMs) dominate the market with direct access to design and product development. They account for over 60% of EDA tool usage, particularly in Tier-1 companies.

EMS Providers

Electronics Manufacturing Services (EMS) firms use EDA tools for design for manufacturability (DFM) and quality assurance. This group contributes approximately 28% to the market.

Others

Other users include design consultancies, startups, and academic institutions. While relatively smaller, this segment comprises about 12% of the total market and is steadily growing.

Electronic Design Automation for PCB and MCM Market, Segmentation by Geography

In this report, the Electronic Design Automation Market has been segmented by Geography into North America, Europe, Asia Pacific, Middle East & Africa, and Latin America.

Electronic Design Automation for PCB and MCM Market Share (%), by Geographical Region

North America

North America leads the global market with over 35% share, driven by the presence of EDA pioneers and semiconductor giants. The U.S. remains a hub for R&D and innovation across industries.

Europe

Europe contributes around 22% to the market, backed by strong demand in automotive, aerospace, and industrial automation. Countries like Germany and France spearhead regional adoption.

Asia Pacific

Asia Pacific holds nearly 30% of the market, propelled by large-scale electronics manufacturing and government-backed tech initiatives in China, Japan, and South Korea.

Middle East & Africa

This region represents about 7% of the global share, gaining momentum with defense investments and smart city developments in GCC countries and South Africa.

Latin America

Latin America accounts for 6% of the market, led by growing demand for consumer electronics and increased design outsourcing in Brazil and Mexico.

This report provides an in depth analysis of various factors that impact the dynamics of Global Electronic Design Automation for PCB and MCM Market. These factors include; Market Drivers, Restraints and Opportunities Analysis.

Drivers, Restraints and Opportunity Analysis

Drivers

• Demand for Miniaturization in Electronics
• Advancements in Semiconductor Technologies
• Growing Adoption of IoT and Wearable Devices

• Automation of Design Processes - Automation of electronic design processes is transforming the electronic design automation (EDA) landscape, enhancing efficiency, reducing time-to-market, and improving overall design accuracy in PCB (Printed Circuit Board) and MCM (Multi-Chip Module) development. Automation technologies leverage algorithms, machine learning, and artificial intelligence (AI) to streamline various aspects of electronic design, from schematic capture and layout optimization to simulation and verification.

  One significant benefit of automation in electronic design is the acceleration of design cycles and the reduction of manual errors. By automating routine design tasks such as component placement, routing, and signal integrity analysis, EDA tools enable designers to focus more on creative aspects and complex problem-solving, thereby enhancing productivity and innovation. Automated design processes also facilitate rapid prototyping and iterative design improvements, allowing designers to explore multiple design iterations efficiently and optimize designs for performance, manufacturability, and cost-effectiveness.

  Looking forward, the evolution of automation technologies is driving opportunities for innovation and advancement in electronic design. Emerging trends such as the Internet of Things (IoT), 5G connectivity, and artificial intelligence (AI) are fueling demand for more sophisticated EDA solutions capable of handling complex design requirements and integrating advanced functionalities. Investments in AI-driven EDA tools, cloud-based design platforms, and digital twins are expected to further enhance automation capabilities, enabling real-time design simulations, predictive analytics, and virtual prototyping in PCB and MCM development. By harnessing the power of automation, electronic design automation providers can empower designers and engineers to create next-generation electronic products that are more efficient, reliable, and tailored to meet the evolving demands of modern technology ecosystems.

Restraints

• Complexity in Integration with Legacy Systems
• Shortage of Skilled EDA Engineers
• Security Concerns in Design Data

• Challenges in Multi-Chip Module (MCM) Integration - Multi-Chip Modules (MCMs) present unique integration challenges in electronic design, primarily due to the complexity of combining multiple semiconductor chips within a single package or substrate. MCMs are designed to enhance functionality, improve performance, and reduce footprint by integrating multiple integrated circuits (ICs) or chips, each performing specialized functions, into a compact module. However, several technical and practical challenges must be addressed to achieve successful MCM integration and ensure optimal performance and reliability of the integrated system.

  Another significant challenge in MCM integration is managing signal integrity and electromagnetic interference (EMI). Integrating multiple chips within a confined space can lead to signal cross-talk, noise coupling, and electromagnetic interference issues that degrade signal quality and affect overall system performance. Designers must employ advanced signal routing techniques, impedance matching, shielding strategies, and isolation techniques to mitigate signal integrity risks and ensure robust electrical performance of MCMs across different operating frequencies and environments.

  Addressing these challenges requires a multidisciplinary approach involving collaboration among semiconductor manufacturers, electronic design automation (EDA) providers, materials suppliers, and packaging specialists. Advances in EDA tools, simulation software, and design methodologies play a crucial role in overcoming MCM integration challenges by enabling comprehensive design analysis, optimization, and validation. By addressing thermal management, signal integrity, EMI mitigation, and manufacturing complexities effectively, designers can harness the potential of MCM technology to deliver innovative, high-performance electronic systems that meet the stringent requirements of modern applications in sectors such as telecommunications, aerospace, automotive, and consumer electronics.

Opportunities

• Development of AI-Driven EDA Solutions
• Emerging Markets in Asia-Pacific
• Integration of 5G Technology

• Collaboration with Semiconductor Foundries - Collaboration with semiconductor foundries is critical for companies involved in electronic design automation (EDA), particularly in the development and manufacturing of integrated circuits (ICs) and semiconductor devices. Semiconductor foundries specialize in the fabrication of semiconductor wafers and the production of ICs based on designs provided by EDA companies and their customers. Foundries offer advanced manufacturing processes, cleanroom facilities, and expertise in semiconductor manufacturing that complement the design capabilities of EDA firms, enabling the realization of complex IC designs into physical silicon chips.

  One of the key benefits of collaboration with semiconductor foundries is access to advanced process technologies and manufacturing capabilities. Foundries invest heavily in research and development to develop and refine semiconductor fabrication processes, such as FinFET (fin field-effect transistor) technology, silicon-on-insulator (SOI) technology, and advanced packaging techniques. Collaborating with foundries allows EDA companies to leverage these cutting-edge technologies to design and produce ICs with smaller feature sizes, higher performance, lower power consumption, and enhanced integration capabilities, meeting the demands of modern electronic applications.

  Collaboration with semiconductor foundries fosters a collaborative ecosystem for innovation and technology advancement in the semiconductor industry. Foundries often collaborate with EDA providers, academic institutions, research organizations, and industry consortia to drive technological innovation, develop new semiconductor materials and processes, and address emerging challenges in semiconductor manufacturing. This collaborative approach enables cross-disciplinary knowledge sharing, facilitates technology transfer, and promotes continuous improvement in semiconductor design, manufacturing, and reliability. By fostering close partnerships with semiconductor foundries, EDA companies can capitalize on synergies, leverage collective expertise, and contribute to the evolution of semiconductor technology to meet the evolving needs of global markets and industries.

Key players in Global Electronic Design Automation for PCB and MCM Market include :

• Zuken
• Infinite Graphics Incorporated
• Mentor Graphics
• Synopsys
• Altium Limited
• Fujitsu
• ANSYS
• Orbotech

In this report, the profile of each market player provides following information:

• Company Overview and Product Portfolio
• Key Developments
• Financial Overview
• Strategies
• Company SWOT Analysis