Microchip unveils PolarFire Core to cut FPGA costs for power-efficient applications

May 29, 2025 /Semi/ — Microchip Technology has launched the PolarFire® Core family of FPGAs and SoCs, targeting customers seeking cost-effective, low-power programmable logic solutions. By eliminating integrated serial transceivers, the new lineup reduces bill-of-material costs by up to 30%, while preserving the core strengths of PolarFire: power efficiency, security, and reliability. The…

Microchip announced its financial report with a year-on-year revenue decline of 48.4%

On November 6, news came that the American chip company Microchip announced its second quarter results for fiscal year 2025 (as of September 30, 2024). This news has drawn extensive attention in the chip industry.

In this quarter, Microchip achieved revenue of 1.164 billion U.S. dollars (currently about 8.266 billion yuan). Although this figure is higher than the midpoint of the guidance given on August 1, it still decreased sharply by 48.4% year-on-year and also decreased by 6.2% quarter-on-quarter, reflecting the challenges currently faced by the chip market.

Among its important financial data, gross margin, operating margin, net income, etc. have different performances under different standards.

Ganesh Moorthy, president and chief executive officer of Microchip, analyzed the performance and said that the company continues to deal with inventory adjustments, and the European business has exacerbated the macro weakness. At the same time, it is pointed out that the progress of “green shoots” is uneven, but some signs are positive signals for the formation of a potential bottom.

For the future, Microchip expects revenue, gross margin, operating margin and other indicator ranges in the third quarter of fiscal year 2025 (as of December 31, 2024).

Microchip is actively responding to challenges and seeking development opportunities in the current market environment.

Summary of ICgoodFind: As an important enterprise in the chip industry, Microchip's performance dynamics have a significant impact on the industry. As an electronic component supplier, ICgoodFind will continue to pay attention to industry changes and provide customers with high-quality electronic component products and professional services. We look forward to Microchip continuing to innovate and making greater contributions to promoting the development of the industry.

Future Electronics to Host Webinar on Microchip's SmartHLS Compiler Software

Future Electronics invites all designers and engineers to join this webinar to gain an in-depth understanding of the advantages of integrating SmartHLS into their next design project.

Future Electronics Webinar on Microchip's to ensure the hardware functionality

Designers often face challenges when migrating designs from one architecture to another. Microchip's SmartHLS compiler software elevates FPGA design abstraction from traditional hardware description languages to C/C++ software.

Mastering VLSI: Why the Right Training Matters for a Thriving Tech Career

The Rising Demand for VLSI Experts The modern world is driven by electronics. From smartphones to smart cars, every innovation depends on microchips designed using VLSI (Very Large Scale Integration) technology. With the growing use of AI, IoT, and automation, the need for skilled VLSI professionals has increased rapidly. This makes VLSI an essential field for those looking to build a strong career in electronics and semiconductor industries. Choosing the right learning path is key to making the most of this opportunity.

Exploring the Benefits of VLSI Online Training Courses Many learners today seek flexible and effective ways to upskill. VLSI online training courses offer an excellent solution by combining convenience with quality education. These courses provide access to experienced instructors, practical assignments, and industry-based projects—all from the comfort of home. Learners can grasp digital design, physical design, verification, and ASIC/FPGA concepts without sacrificing their job or academic responsibilities. The online model also allows repeated learning and flexible scheduling, making it ideal for beginners as well as professionals wanting to upgrade their knowledge.

Choosing the Right Learning Mode While online learning provides flexibility, some individuals prefer classroom-based teaching for real-time interaction and immediate doubt clearing. The choice between online and offline modes largely depends on individual preferences, learning habits, and career goals. However, what truly matters is the quality of the training and the expertise of the instructors involved.

Key Skills Taught in VLSI Training A well-structured VLSI course should cover areas like CMOS technology, HDL languages such as Verilog and VHDL, physical design flow, and functional verification techniques. Practical exposure through lab sessions or simulation tools is crucial. Additionally, learners should be guided on real-time projects to apply their theoretical knowledge to industry problems.

Why VLSI Coaching in Hyderabad is Gaining Popularity Hyderabad has become a major hub for semiconductor and electronics industries. As a result, VLSI coaching in Hyderabad has gained recognition for producing skilled professionals. Reputed training centers in the city offer tailored coaching with an industry-aligned curriculum, experienced faculty, and placement support. Many aspirants from across the country travel to Hyderabad to benefit from this coaching environment that bridges academic learning with industry demands.

Conclusion VLSI technology plays a vital role in shaping the electronics and semiconductor industries. Whether through VLSI online training courses or classroom-based programs like VLSI coaching in Hyderabad, acquiring the right skills is essential for career growth. Institutions like Takshila Institute of VLSI Technologies provide training that matches industry standards, helping learners succeed in a competitive field. The choice of platform and location may differ, but the goal remains the same—building a strong foundation in VLSI for a successful future.

Global FPGA Market to Expand at 8.1% CAGR Through 2031

The global field-programmable gate array (FPGA) market, valued at US$ 6 Bn in 2020, is poised for robust growth. According to market projections, the FPGA market is expected to expand at a CAGR of 8.1% from 2021 to 2031, reaching US$ 13.6 Bn by the end of 2031. This growth is attributed to the surge in data center deployments, advancements in 5G infrastructure, and the growing use of FPGA in diverse sectors including automotive, aerospace, and telecommunications.

Market Overview: FPGAs are integrated circuits that can be configured post-manufacturing, making them highly flexible and suitable for a variety of applications such as video/image processing, industrial automation, and Big Data analytics. Their reprogrammable nature and compact design allow for rapid innovation and product adaptation. FPGAs play a critical role in supporting high-performance computing systems, which are becoming integral to industries across the globe.

Market Drivers & Trends

The primary drivers fueling the growth of the FPGA market include:

Rising demand for data centers to handle massive volumes of real-time information generated by IoT devices.

Adoption of 5G networks, requiring sophisticated RF signal processing and data transmission capabilities.

Integration in automotive systems, especially in advanced driver-assistance systems (ADAS), infotainment, and safety applications.

Increased investment in industrial automation, consumer electronics, and military applications.

A major trend reshaping the market is the shift toward SRAM-based FPGA devices, which offer superior reconfiguration capabilities and are preferred for high-reliability applications in aerospace and communications.

Latest Market Trends

FPGA in 5G Infrastructure: Modern 5G NR base stations utilize FPGAs for high-speed data routing and processing. For instance, Xilinx’s Zynq UltraScale+ RFSoC is tailored to support remote radio heads and backhaul systems.

Rise of AI and ML Applications: The reprogrammability of FPGAs makes them suitable for evolving AI workloads, where data paths need constant updates for optimization.

Edge Computing: Deployment of edge computing systems is increasing demand for low-latency, high-throughput FPGA components.

Key Players and Industry Leaders

Several global companies are at the forefront of the FPGA market. Notable names include:

Xilinx, Inc.

Intel Corporation

Microchip Technology Inc.

Lattice Semiconductor Corporation

QuickLogic Corporation

Efinix Inc.

GOWIN Semiconductor Corporation

Achronix Semiconductor Corporation

Microsemi Corporation

These companies are driving innovation through continuous R&D, strategic acquisitions, and product launches.

Recent Developments

Lattice Semiconductor introduced the Lattice Mach-NX FPGA in December 2020, aimed at secure control applications in industrial, computing, and automotive sectors.

Microchip Technology Inc. launched PolarFire SoC, a RISC-V-based FPGA, to serve power-sensitive applications.

Xilinx Inc. unveiled Kintex Ultrascale XQRKU060 FPGA targeting space-grade computing applications.

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Market Opportunities

Post-pandemic recovery has revealed new opportunities in healthcare, telecommunications, and automotive electronics where FPGA use is surging.

5G and IoT proliferation provide long-term opportunities for FPGA makers to embed their solutions in real-time data processing and communications infrastructure.

Automotive applications such as electric vehicles and autonomous driving systems are expected to increasingly rely on FPGA for system control and processing.

Future Outlook

Over the next decade, the FPGA market is expected to witness:

Greater diversification into new industries, including renewable energy and smart grids.

Widespread adoption in defense systems, especially in avionics, radar, and secure communication platforms.

Increase in cloud-based FPGA solutions offering scalable and on-demand FPGA compute resources.

The high demand from data-intensive sectors, combined with the benefits of FPGA’s flexibility and efficiency, positions the technology as a critical enabler of future digital transformation.

Market Segmentation

By Configuration

Low-end FPGA

Mid-range FPGA

High-end FPGA

By Node Size

≤28 nm

28–90 nm

90 nm

By Architecture

SRAM-based FPGA

Anti-fuse-based FPGA

Flash-based FPGA

By End-use Industry

Consumer Electronics

IT & Telecommunication

Aerospace & Defense

Industrial

Others (Automotive & Transportation, Healthcare)

Regional Insights

Asia Pacific is the fastest-growing region in the FPGA market, led by countries such as China, Japan, and India. These nations are witnessing rapid growth in data center construction, consumer electronics manufacturing, and 5G deployments.

North America, led by the U.S., remains a key hub due to a mature technology ecosystem and high investment in defense and automotive industries.

Europe is expected to maintain steady growth, particularly in automotive and industrial automation sectors, while South America and the Middle East & Africa are gradually emerging with growing ICT infrastructures and government investments.

Why Buy This Report?

Provides in-depth analysis of market dynamics, including drivers, restraints, and opportunities.

Includes regional and segment-wise insights to support strategic decision-making.

Features competitive landscape and profiling of key players with their latest strategies and innovations.

Offers forecast data up to 2031, helping businesses plan long-term strategies.

Covers emerging trends and technologies shaping the FPGA landscape.

Frequently Asked Questions

1. What is the current size of the global FPGA market? As of 2020, the market was valued at US$ 6 Bn.

2. What is the projected value of the FPGA market by 2031? The FPGA market is expected to reach US$ 13.6 Bn by the end of 2031.

3. What is driving the growth of the FPGA market? The market is driven by data center expansion, 5G infrastructure development, increasing applications in automotive and aerospace sectors, and advancements in AI and IoT.

4. Who are the major players in the FPGA market? Key players include Xilinx, Intel, Microchip Technology, Lattice Semiconductor, Efinix, and QuickLogic.

5. Which region is expected to grow the fastest? Asia Pacific, due to rapid industrialization, growing consumer demand, and robust 5G deployment.

6. What are the major end-use industries? Consumer electronics, IT & telecom, aerospace & defense, industrial automation, automotive, and healthcare.

At Voler Systems, our embedded systems digital circuit design engineers specialize in developing FPGA designs with industry-leading platforms such as Xilinx, Intel (formerly Altera), and Microchip . Our breadth of experience enables us to tackle complex design challenges, ensuring seamless system integration, optimized architecture development, and robust design performance.

Embedded Field-Programmable Gate Array (FPGA) Market Comprehensive Analysis and Future Forecast

The market, valued in 2023, is expected to experience significant growth by 2032, driven by a strong compound annual growth rate (CAGR) from 2024 to 2032.

Analysis of the Market | Research Report [2024-2032] - https://www.globalmarketstatistics.com/market-reports/embedded-field-programmable-gate-array-fpga-market-11493

The "Embedded Field-Programmable Gate Array (FPGA) Market" Research Report provides a comprehensive analysis of industry trends, growth, and opportunities, categorized by types (Eeprom, Antifuse, Sram) and regional outlook. It includes forecasts spanning from 2024 to 2032.

Browse the detailed TOC of the Embedded Field-Programmable Gate Array (FPGA) Market report, featuring comprehensive tables, figures, and charts that offer exclusive data, vital statistics, key trends, and insights into the competitive landscape of this niche sector.

Who is the largest manufacturers of Embedded Field-Programmable Gate Array (FPGA) Market worldwide?

Intel (U.S.)

Xilinx (U.S.)

Lattice Semiconductor (U.S.)

Microchip Technology (U.S.)

Achronix (U.S.)

Flex Logix (U.S.)

Menta (France)

Efinix (Malaysia)

NanoXplore (Canada)

QuickLogic (U.S.)

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Short Description About Embedded Field-Programmable Gate Array (FPGA) Market:

The global Embedded Field-Programmable Gate Array (FPGA) Market market is poised for remarkable growth during the forecast period of 2024 to 2032. After demonstrating steady expansion in 2023, the market is set to accelerate further, driven by the rising adoption of innovative strategies and initiatives by leading industry players, ensuring strong growth momentum throughout the projected timeline.

North America, especially The United States, will still play an important role which cannot be ignored. Any changes from United States might affect the development trend of Rosin Ester. The market in North America is expected to grow considerably during the forecast period. The high adoption of advanced technology and the presence of large players in this region are likely to create ample growth opportunities for the market.

Europe also play important roles in global market, with a magnificent growth in CAGR During the Forecast period 2024-2032.

Embedded Field-Programmable Gate Array (FPGA) Market size is projected to reach Multimillion USD by 2032, In comparison to 2024, at unexpected CAGR during 2024-2032.

Despite the presence of intense competition, due to the global recovery trend is clear, investors are still optimistic about this area, and it will still be more new investments entering the field in the future.

This report focuses on the Embedded Field-Programmable Gate Array (FPGA) Market in global market, especially in North America, Europe and Asia-Pacific, South America, Middle East and Africa. This report categorizes the market based on manufacturers, regions, type and application.

The report focuses on the Embedded Field-Programmable Gate Array (FPGA) Market size, segment size (mainly covering product type, application, and geography), competitor landscape, recent status, and development trends. Furthermore, the report provides detailed cost analysis, supply chain.

Technological innovation and advancement will further optimize the performance of the product, making it more widely used in downstream applications. Moreover, Consumer behavior analysis and market dynamics (drivers, restraints, opportunities) provides crucial information for knowing the Co-Living market Research Overview | [2024-2032] - https://www.globalmarketstatistics.com/market-reports/embedded-field-programmable-gate-array-fpga-market-11493

What are the types of Embedded Field-Programmable Gate Array (FPGA) Market available in the Market?

Based on Product Types the Market is categorized into Below types that held the largest Embedded Field-Programmable Gate Array (FPGA) Market share In 2023.

Eeprom

Antifuse

Sram

Which regions are leading the Embedded Field-Programmable Gate Array (FPGA) Market?

North America (United States, Canada and Mexico)

Europe (Germany, UK, France, Italy, Russia and Turkey etc.)

Asia-Pacific (China, Japan, Korea, India, Australia, Indonesia, Thailand, Philippines, Malaysia and Vietnam)

South America (Brazil, Argentina, Columbia etc.)

Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa)

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This Embedded Field-Programmable Gate Array (FPGA) Market Research/Analysis Report Contains Answers to your following Questions

What are the global trends in the Embedded Field-Programmable Gate Array (FPGA) Market? Would the market witness an increase or decline in the demand in the coming years?

What is the estimated demand for different types of products in Rosin Ester? What are the upcoming industry applications and trends for Embedded Field-Programmable Gate Array (FPGA) Market?

What Are Projections of Global Embedded Field-Programmable Gate Array (FPGA) Market Industry Considering Capacity, Production and Production Value? What Will Be the Estimation of Cost and Profit? What Will Be Market Share, Supply and Consumption? What about Import and Export?

Where will the strategic developments take the industry in the mid to long-term?

What are the factors contributing to the final price of Rosin Ester? What are the raw materials used for Embedded Field-Programmable Gate Array (FPGA) Market manufacturing?

How big is the opportunity for the Embedded Field-Programmable Gate Array (FPGA) Market? How will the increasing adoption of Embedded Field-Programmable Gate Array (FPGA) Market for mining impact the growth rate of the overall market?

How much is the global Embedded Field-Programmable Gate Array (FPGA) Market worth? What was the value of the market In 2023?

Who are the major players operating in the Embedded Field-Programmable Gate Array (FPGA) Market? Which companies are the front runners?

Which are the recent industry trends that can be implemented to generate additional revenue streams?

What Should Be Entry Strategies, Countermeasures to Economic Impact, and Marketing Channels for Embedded Field-Programmable Gate Array (FPGA) Market Industry?

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Detailed TOC of Global Embedded Field-Programmable Gate Array (FPGA) Market Research Report, 2024-2032

1 Market Overview 1.1 Product Overview and Scope of Rosin Ester 1.2 Classification of Embedded Field-Programmable Gate Array (FPGA) Market by Type 1.2.1 Overview: Global Embedded Field-Programmable Gate Array (FPGA) Market Size by Type: 2017 Versus 2022 Versus 2032 1.2.2 Global Embedded Field-Programmable Gate Array (FPGA) Market Revenue Market Share by Type in 2022 1.3 Global Embedded Field-Programmable Gate Array (FPGA) Market by Application 1.3.1 Overview: Global Embedded Field-Programmable Gate Array (FPGA) Market Size by Application: 2017 Versus 2022 Versus 2032 1.4 Global Embedded Field-Programmable Gate Array (FPGA) Market Size and Forecast 1.5 Global Embedded Field-Programmable Gate Array (FPGA) Market Size and Forecast by Region 1.6 Market Drivers, Restraints and Trends 1.6.1 Embedded Field-Programmable Gate Array (FPGA) Market Drivers 1.6.2 Embedded Field-Programmable Gate Array (FPGA) Market Restraints 1.6.3 Embedded Field-Programmable Gate Array (FPGA) Market Trends Analysis

2 Company Profiles 2.1 Company 2.1.1 Company Details 2.1.2 Company Major Business 2.1.3 Company Embedded Field-Programmable Gate Array (FPGA) Market Product and Solutions 2.1.4 Company Embedded Field-Programmable Gate Array (FPGA) Market Revenue, Gross Margin and Market Share (2020,2021,2022, and 2023) 2.1.5 Company Recent Developments and Future Plans

3 Market Competition, by Players 3.1 Global Embedded Field-Programmable Gate Array (FPGA) Market Revenue and Share by Players (2020,2021,2022, and 2023) 3.2 Market Concentration Rate 3.2.1 Top3 Embedded Field-Programmable Gate Array (FPGA) Market Players Market Share in 2022 3.2.2 Top 10 Embedded Field-Programmable Gate Array (FPGA) Market Players Market Share in 2022 3.2.3 Market Competition Trend 3.3 Embedded Field-Programmable Gate Array (FPGA) Market Players Head Office, Products and Services Provided 3.4 Embedded Field-Programmable Gate Array (FPGA) Market Mergers and Acquisitions 3.5 Embedded Field-Programmable Gate Array (FPGA) Market New Entrants and Expansion Plans

4 Market Size Segment by Type 4.1 Global Embedded Field-Programmable Gate Array (FPGA) Market Revenue and Market Share by Type (2017-2023) 4.2 Global Embedded Field-Programmable Gate Array (FPGA) Market Forecast by Type (2023-2031)

5 Market Size Segment by Application 5.1 Global Embedded Field-Programmable Gate Array (FPGA) Market Revenue Market Share by Application (2017-2023) 5.2 Global Embedded Field-Programmable Gate Array (FPGA) Market Forecast by Application (2023-2032)

6 Regions by Country, by Type, and by Application 6.1 Embedded Field-Programmable Gate Array (FPGA) Market Revenue by Type (2017-2032) 6.2 Embedded Field-Programmable Gate Array (FPGA) Market Revenue by Application (2017-2032) 6.3 Embedded Field-Programmable Gate Array (FPGA) Market Size by Country 6.3.1 Embedded Field-Programmable Gate Array (FPGA) Market Revenue by Country (2017-2031) 6.3.2 United States Embedded Field-Programmable Gate Array (FPGA) Market Size and Forecast (2017-2032) 6.3.3 Canada Embedded Field-Programmable Gate Array (FPGA) Market Size and Forecast (2017-2032) 6.3.4 Mexico Embedded Field-Programmable Gate Array (FPGA) Market Size and Forecast (2017-2032)

7 Research Findings and Conclusion

8 Appendix 8.1 Methodology 8.2 Research Process and Data Source 8.3 Disclaimer

9 Research Methodology

10 Conclusion

Continued….

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About Us: Global Market Statistics is committed to delivering expert analysis and precise, data-driven market insights. We empower businesses, regardless of their size, with tailored solutions designed to address their specific challenges. Our services equip clients to anticipate and navigate potential market shifts, ensuring they remain competitive in an ever-evolving business environment.

Best VLSI Projects for ECE Students

Very Large Scale Integration (VLSI) is a crucial domain in Electronics and Communication Engineering (ECE), offering opportunities to design and develop microchips and complex electronic circuits. Here are some of the best VLSI project ideas for ECE students that can enhance their knowledge and career prospects:

FPGA-Based System Design: Field-Programmable Gate Arrays (FPGAs) are widely used in the industry for prototyping. Students can design a system using FPGA for applications such as real-time video processing, digital signal processing, or cryptography.

Low-Power VLSI Design: With the growing demand for energy-efficient devices, low-power VLSI design projects like creating low-power adders, multipliers, or memory circuits can be impactful and highly relevant.

ASIC Design for IoT Applications: Application-Specific Integrated Circuits (ASICs) are tailored for specific purposes. Designing ASICs for IoT devices, such as smart sensors or wearable technology, is a cutting-edge project idea.

Digital Signal Processing (DSP) Architecture: DSP is critical for applications like audio processing, image processing, and telecommunications. Implementing DSP algorithms on VLSI platforms offers practical insights.

High-Speed Processor Design: Designing processors with high-speed operation and reduced latency is a challenging yet rewarding project. Focus on architectures like RISC or multi-core processors.

Memory Design and Optimization: Projects focusing on memory units such as SRAM, DRAM, or Flash memory can help students understand memory hierarchy, speed, and power trade-offs.

Verification and Testing of VLSI Circuits: Verification ensures the accuracy of designs before fabrication. Projects in this area can include creating automated verification environments using tools like Verilog or SystemVerilog.

By undertaking these projects, students not only gain technical expertise but also develop problem-solving and analytical skills, preparing them for a thriving career in the VLSI industry.

FPGA Market in the United States: Industry Trends, Forecast, and Competitive Analysis

Increasing government investments and rising demand for FPGA in automotive and data center sectors to boost market in the country.

The FPGA market in US is experiencing high growth due to economic stability of the country, leading technologies, and increased demand in computing solutions across different sectors. Major players such as Advanced Micro Devices, Inc., Intel Corporation, Microchip Technology, and Lattice Semiconductor Corporation in the region create competitive advantages for the expansion of FPGA market. Rising military spending is an important growth driver, with substantial budget allocated to FPGA-based military communication systems, radar, signal processing, and cybersecurity. US military spending, for example, reached USD 820 billion in 2023 with ongoing investments in edge computing and AI-enabled systems that employ FPGAs. These factors point to the importance of FPGAs in supporting the nation's technological superiority and security initiatives.

Another key driver of the FPGA market is the expansion of the US data center industry. With nearly 1,974 operational data centers, the US accounts for 33% of the global total, as the Data Center Map states. Data centers are widely adopting FPGAs to improve high-bandwidth connections, process large-scale data storage, and increase the computational efficiency. These capabilities make FPGAs an essential component for handling important applications like big data analytics and cloud services. The widespread network of data centers as well as increasing demand for advanced computation create new opportunities for local FPGA providers to scale up their solutions.

The US automotive sector is using FPGAs for applications such as Advanced Driver Assistance Systems (ADAS), sensor fusion, battery management, and infotainment systems. FPGA solutions are being implemented by leading manufacturers such as Tesla, Ford, and General Motors to process in real time the data of multiple sensors for enhanced vehicle safety and efficiency. In 2023, the US automotive industry produced over 10.6 million vehicles, with 6% year-on-year growth. The increasing adoption of autonomous and electric vehicle applications, is expected to drive FPGA demand further in automotive industry.

Robotics and industrial automation are transforming the US manufacturing sector, with FPGA playing a key role. The rise in robotic startups such as Bright Machines and RightHand Robotics represents increasing emphasis on smart factories, sensor automation and AI-driven robotics. FPGA technology is being leveraged by these startups for developing robust hardware-software ecosystems for industrial automation.

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Government fundings and research programs further boost the growth of the FPGA market. In February 2023, DARPA granted USD 25 million to develop an FPGA-based radar system that would be more flexible and agile than existing systems. Such investments reflect the commitment of the US government to develop FPGA technology. With strong governmental support and the presence of leading market players, the US is in a good position to retain its leadership in FPGA technology and to capitalize on emerging opportunities in the global market.

Future Electronics and Power Integrations to Host Seminar on Electronics Design

During the seminar, participants will gain first-hand insights from global leaders on cutting-edge technologies shaping the future of electronics. Topics will include advancements in human-machine interfaces, power efficiency, cryptography, and field programmable gate arrays (FPGAs). Attendees will also delve into Microchip's latest microcontroller innovations and Power Integrations' pioneering power conversion solutions.

Discover the Right VLSI Training Destination to Shape a Bright Career

The Growing Demand for VLSI Professionals The world is moving rapidly towards automation, smart electronics, and cutting-edge semiconductor technologies. As a result, VLSI (Very Large Scale Integration) has become a crucial domain in the electronics industry. It plays a significant role in designing compact, high-performance integrated circuits that power modern electronic devices. This increasing reliance on microchips has sparked a strong demand for skilled VLSI professionals across India and beyond. For those aiming to build a career in semiconductor design, selecting the right training institute becomes the first and most important step.

Why Hyderabad is a Preferred City for VLSI Training Hyderabad has emerged as a major hub for semiconductor companies and research institutions, making it an ideal location for VLSI training. The presence of leading IT parks, development centers, and electronics manufacturing companies has led to the establishment of several reputed training institutes. Among the top vlsi training institutes in hyderabad, students often seek those that offer practical learning, expert faculty, and strong placement support. These institutes are known for their industry-oriented curriculum, state-of-the-art labs, and real-time project training. Hyderabad continues to attract VLSI aspirants due to its affordable cost of living, quality education, and vast opportunities in the electronics sector.

Essential Features of a Good VLSI Training Program A quality VLSI training program focuses not only on theoretical knowledge but also on practical skills development. It typically covers ASIC design, FPGA design, Verilog, VHDL, SystemVerilog, and related tools such as Cadence and Synopsys. The use of real-time projects allows students to gain confidence and familiarity with industry practices. Faculty with real-world experience in chip design and verification can make a huge difference in understanding the practical challenges of VLSI projects. A good institute should also provide access to placement assistance, resume preparation, and interview coaching to enhance employability.

Key Factors to Consider While Choosing a VLSI Institute Selecting the right institute can have a long-lasting impact on one’s career. Factors such as the curriculum, infrastructure, faculty experience, placement records, and alumni feedback should be considered carefully. Also, institutes that maintain strong industry collaborations often provide better internship and job opportunities. Personalized mentorship, exposure to real-time tools, and soft skills training further improve the chances of landing a job in reputed companies. Ensuring these elements are part of the training structure can help learners stay ahead in the competitive VLSI job market.

Bangalore’s Role in Advancing VLSI Careers Bangalore, known as India’s Silicon Valley, also stands tall in offering top-tier VLSI education. It is home to several reputed vlsi training institutes in bangalore, many of which have strong industry connections and advanced lab facilities. The proximity to global semiconductor giants and tech startups makes Bangalore an ideal location for gaining hands-on experience. Institutes in the city are known for organizing workshops, internships, and campus placements that prepare students for real-world job roles in VLSI design and verification. The exposure to an innovation-driven environment gives learners an added advantage in shaping a successful career.

Conclusion VLSI is a fast-evolving field that requires focused training and continuous upskilling. Choosing a city like Hyderabad or Bangalore, both equipped with academic excellence and industry presence, can significantly boost one’s career prospects. Whether enrolling in one of the top vlsi training institutes in hyderabad or exploring options among the vlsi training institutes in bangalore, learners should evaluate all aspects of a training program before committing. In the middle of this growing demand, Takshila Institute of VLSI Technologies has gained recognition for providing high-quality education and consistent placement support. Ultimately, the right training from a credible institute can open doors to a rewarding future in the semiconductor industry.

How AI and Defense Initiatives Are Shaping the Semiconductor IP Market

The global semiconductor intellectual property (IP) market was valued at US$ 7.1 billion in 2023 and is expected to grow at a compound annual growth rate (CAGR) of 5.9%, reaching US$ 13.5 billion by 2034. The market is being propelled by the rising demand for AI-based applications, government initiatives to modernize defense technologies, and advancements in semiconductor IP commercialization strategies.

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Top Market Trends

AI-Driven Growth: AI-based applications, particularly deep learning (DL) neural networks, are significantly influencing the demand for robust semiconductor IP solutions. AI systems rely on highly efficient and customizable IP cores to enhance processing power, reduce latency, and improve energy efficiency.

Security and Encryption Technologies: As digital threats grow, Hardware Root of Trust (HRoT) and encryption/decryption solutions are becoming critical in semiconductor IP, particularly in defense, IoT, automotive, and industrial applications.

Commercialization of Captive Semiconductor IP: Key players in the industry are developing new business models to commercialize in-house semiconductor IP. This trend is driving innovation and enabling companies to unlock additional revenue streams.

Regional Market Expansion: While North America leads in semiconductor IP due to investments in semiconductor manufacturing and security measures, Asia Pacific is rapidly expanding, with China dominating global semiconductor production and consumption.

Government Investments in Semiconductor Manufacturing: Policies such as the U.S. CHIPS and Science Act are catalyzing semiconductor manufacturing and IP development, ensuring a steady market growth trajectory.

Analysis of Key Players

Key players operating in the global Semiconductor IP market are focusing on licensing ASIC and FPGA semiconductor IP solutions and patent licensing. They are licensing their broad portfolio of memory interface patents to semiconductor and systems companies.

Arm Limited, Rambus, Synopsys, Inc., CEVA, Inc., Maven Silicon, Cadence Design Systems, Inc., Microchip Technology Inc., Achronix Semiconductor Corporation, Marvell, Imagination Technologies, Lattice Semiconductor, Menta, Taiwan Semiconductor Manufacturing Company Limited, Movellus, and Allegro DVT are key players operating in the semiconductor IP industry.

Key Market Drivers

Demand for AI-based Applications: AI, DL, and machine learning (ML) applications are accelerating the demand for high-performance semiconductor IP solutions.

Government Initiatives in Defense Technologies: Defense organizations globally are integrating semiconductor IP to enhance security and performance in military-grade applications.

Increase in Semiconductor Manufacturing Investments: Significant investments in semiconductor fabs and advanced chip manufacturing, particularly in North America and Asia Pacific, are driving market expansion.

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Market Challenges

Intellectual Property Theft and Security Risks: As semiconductor IP gains more prominence, issues related to unauthorized access and IP theft are increasing, posing challenges for industry players.

High R&D Costs: Developing new semiconductor IP solutions requires significant investments in research and development, which can be a barrier for new entrants.

Regulatory and Compliance Issues: The semiconductor IP industry is subject to stringent regulations, especially concerning data security and export controls, which can affect market growth.

Market Segmentation

By Type

Processor IP

Memory IP

Interface IP

ASIC

Verification IP

By Architecture Design

Hard IP Core

Soft IP Core

By IP Source

Licensing

Royalty

By End-user

Integrated Device Manufacturer (IDM)

Foundry

Others

By Industry Vertical

Consumer Electronics

Telecommunications & Data Center

Industrial

Automotive

Commercial

Healthcare

Others

Future Outlook The semiconductor IP market is expected to witness steady growth due to the increasing integration of AI into consumer electronics, automotive, and industrial applications. Furthermore, as AI-driven systems require more advanced SoC architectures, semiconductor IP providers will continue innovating to meet market demands. Investments in security solutions, particularly encryption and HRoT, will remain a focal point for market growth.

Future Prospects: What’s Next for the Industry?

Advancements in Neural Network Processing (NNP): AI-driven processing requirements will continue to shape semiconductor IP, leading to more sophisticated and efficient chip architectures.

Integration of Physical Unclonable Functions (PUF): Security technologies such as PUF are expected to play a significant role in ensuring semiconductor IP integrity.

Expansion of IP Licensing and Royalty Models: Companies will increasingly focus on licensing and royalty-based revenue models to optimize IP monetization.

Strategic Collaborations and Acquisitions: Key players will engage in partnerships and acquisitions to strengthen their semiconductor IP portfolios.

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The Future of Digital Circuits: Voler Systems' FPGA Solutions at the Forefront

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In today's fast-paced technological landscape, the ability to innovate and adapt is crucial. With Voler Systems' FPGA solutions, businesses gain a competitive edge, harnessing the power of FPGA technology to redefine digital circuit performance. Whether you're developing the next breakthrough medical device or optimizing data processing systems, our FPGA design expertise positions you for success in a dynamic and demanding market.