Field Programmable Gate Array (FPGA) Market
By Type (FPGA, eFPGA),
By Node Size (Less than or equal to 16NM,20NM to 90NM, More than 90NM),
By Technology (EEPROM, SRAM, FLASH, Antifuse, Others),
By End-Use Industry (IT and telecom, Consumer and electronics, Automotive and industrial, aerospace and defense),
By Region (North America, Europe, Asia-Pacific, Latin America, Middle East & Africa):
Global Analysis and Forecast 2023-2033
The global field programmable gate market showcased revenue of USD 4.21 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 17.19% over the forecast period of 2023-2033.
Russia-Ukraine War Impact
Market Scope
About the Market
Impact of COVID-19
Global Economic Slowdown
Market Dynamics
Driver
Restrain
Opportunity
Recent Developments
Synopsis
How is this report helpful
FAQ's
Report Coverage
Related Reports
In general meaning field programmable gate arrays (FPGA) are semiconductor programmable chips that are made up of silicon with a collection of programmable logic blocks surrounded by input or output blocks that are put together through programmable resources to become any digital circuit or system. These are the general-purpose logic devices that end users can use to perform many tasks and functions that are different, logical, and complex. It is also used for prototyping logic hardware.
It is an electronic device embedded system, also called –place programmable, and it can be modified in the field without dissembling the system and even without returning the device or system. These are the matrix-configured logic blocks connected with programmable interconnections. They allow consumers to reconfigure the hardware devices to meet the specific in-case use demand even after manufacturing. A kind of integrated circuit that can be reprogrammed to the required use and the functionality or application after manufacturing.
The demand for the field programmable gate array market is increasing due to its various applications that trigger more growth in the North-American region. Some major benefits of the FPGA include lower complexity, higher speed, volume, designs, and programmable functions. They can be worked or programmed according to the desired state or function. The shape of the hardware can be changed according to the need of the users, making it a less complex device, programmable as per the need of the users without being dissembled further, and appropriate volume and designs are quite adjustable to the situation in which the device is being used. It can be configured easily by the consumers without going to the manufacturer. It can be reshaped as per need even after the manufacturing process.
Impact of Russia-Ukraine War on Field-Programmed Gate Array Market
There is a direct impact of the Russia-Ukraine war on the global field programmable gate array market. However, the European region will witness the highest impact. Increased trade sanctions across the European region, followed by disruption in global trade routes, are one of the major factors imposed due to war and limiting business opportunities. Economic sanctions on multiple countries due to the war between the two countries surge the prices of the commodity and disturb the trade, supply chain, and trade of the market globally. The war between the two nations has not only disrupted the chances of economic recovery but also slowed down the global market of the field programmable gate array. Due increase in inflation in the European region and disruption in the global supply chain affected the market of field programmable gate array market negatively because the device is made of semiconductor chips that are made up of silicon, are largely imported from Ukraine, and Palladium is also an important substance that is involved in making of the semiconductor chips are exported from Russia . Shortages of raw materials involved in the manufacturing of devices make it costlier and more difficult to meet the demand of the situation.
Field Programmable Gate Array: Market Scope
The Field Programmable Gate Array (FPGA) market is divided into four segments: node size, technology, and end-use industry. Furthermore, these segments are subdivided into respective categories and cross-referenced to North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa for regional analysis. The type segment is further categorized into FPGA and eFPGA. The node size segment is segregated into less than or equal to 16NM,20NM-90NM, and more than 90NM. The technology segment of the field programmable gate array market is bifurcated into EEPROM, SRAM, FLASH, anti-fuse, and others. End-use industry segment is segregated into IT and telecom, consumer and electronics, automotive and industrial, and aerospace and defense. The business model segment is segregated into one-time purchases, subscriptions, and hybrid. Each of these segments is further classified into regions: North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa. The historical dataset of 2018-2022 is provided in the report, whereas the forecast period of 2023-2033 is offered.
eFPGA will witness the highest growth rate within the offering type segment
In the field programmable gate array in the type segment, the eFPGA witnessed the highest market growth in the upcoming period .eFPGA is the embedded field programmable gate array, a kind of digital block in your SoC like ARM or RISC-V processor. It is just like a digital core of a standard FPGA chip so that you can eliminate a chip with the expensive chips and programmers .eFPGA is an IP core integrated into ASIC that offers flexibility to the users for programmable logic without the cost of the FPGAs. It is a way to instantiate FPGA flexibility inside the SoC without the burden of external FPGA overhead. It also enables the users to have working flexibility in those areas where the protocol, algorithms, and market requirements are changing continuously.FPGA is the technology that changes its RTL designs when users customize its functionality, but in eFPGA, when the developers customize its functionality in post-production, its effects will not change the RTL designs. Some examples of FPGA are Xilinx Spartan 7, Digilent Basys 3, Mojo FPGA, and Altera DE2.
20NM to 90NM will capture the highest market share between 2023-2033
In nodal size segment of the 20NM-90NM will witness the highest market growth in the upcoming forecast period. The 20 NM lithography process is a half-node semiconductor process used as a stop-gap between 22NM and 16NM processes. The FPGA with a node size between 20NM to 90NM offers high-temperature tolerance consumers less power and also acts as a digital signal processing. They offer high density and increased memory and also provide the ease of packaging that makes it more demandable than any other segment of the nodal size. There is a huge demand for the 20NM-90NM node sizes in the vehicles industry and also in networking. In contrast, 90Nm is the technology that is used by the companies like Intel when they plan to produce very small-scale nanotechnology-based semiconductors chips.
The SRAM segment will capture the highest market share in the coming years
In the technology type segment, SRAM will witness the highest growth in the upcoming forecast period. SRAM is a static random access memory that holds the data bits in its memory as long as power is supplied to the system.SRAM does not have to be refreshed every time; unlike DRAM, it does not have this requirement that results in better performance and lower power usage.SRAM provides direct interaction with the CPU at a very high speed that requires much less power consumption in the system.SRAM is a volatile memory because there will be no data when power is restored to the system.SRAM loses memory when the power is removed or removed from the system. At the same time, EEPROM is the electrically erasable programmable read-only memory, a user-modified form of ROM that can be erased and reprogrammed again by applying an electrical voltage higher than the normal voltage.FLASH is also an electronic memory storage medium that can be erased and reprogrammed whenever needed. Antifuse is an electrically programmed terminal device having a small area, low capacitance, and resistance.
The IT and Telecom segment will capture the highest growth rate within the forecast period
In the end-use industry segment of the field programmable gate array market, IT and telecom will witness the highest market growth in the upcoming forecast period. IT and telecom are the major sectors that use the field programmable gate array. The most required things in the IT and telecom sectors today are semiconductor chips and the integrated circuit with less complexity than the FPGA offers. All electronic devices like computers and vehicles require FPGA technology for their convenience and easier application. Laptops that are manufactured in the IT industry require chips of semiconductors ranging between 20NM-90Nm due to their high-density quality, less requirement of power, and high tolerance to temperature and heat.FPGA is also used in the consumer and electronics industry for the manufacturing of electronics that are cost-effective and innovative products. It is also used in various industries like automotive and industrial, aerospace, and defense.
Asia-Pacific to witness the highest growth rate during the forecast period
Asia-Pacific region is promising a dynamic rise in disposable income, which is expected to trigger growing market consumption of cloud gaming-based games and products. Developed countries like U.S., UK, Germany, and Singapore are exploding with the surge in demand for field programmable gate arrays. The Asia-Pacific region is also witnessing the rising integration of various FPGA-related products. This attributes to the rise in the adoption of high-end technology-based devices and the growing demands of consumers for low-price and efficient technology. Countries like India and China are also moving towards the field programmable gate array market to meet the high-end demands of the users. Many companies are recently working to explore and develop this technology more for more technological advancement.
Impact of COVID-19 on field programmable gate array market
COVID-19 had a significant impact on the market of the field programmable gate array market.COVID-19 was an unprecedented global public health emergency that affected almost every industry in the world. During the phase of COVID-19, there was an increase in the usage of electronic devices due to the lockdown that happened globally made a shift of office to work from home, required more employees to have systems for working, increased the demand for semiconductors chips FPGA circuits and software but due to shortage of these things that are required for the manufacturing of electronics increased the demand of electronic devices and other electrical vehicles and cars and disruptions in the supply chain caused the shortage of the product.
Field Programmable Gate Array: Market Dynamics
The market dynamics section of the report covers a depth analysis of drivers, restraints, and opportunities impacting the field programmable gate array market. The report also encompasses major market strategies practiced by the industry, followed by patent analysis, product analysis, competitive benchmarking of companies, various analysis of the artificial intelligence industry, pricing analysis, and geographic competitiveness to provide a detailed understanding. The major players are operating. These companies cumulatively hold the majority of the field programmable gate array market share and actively undergoes strategic development such as new product launches, mergers, collaborations, business expansions, acquisitions, and long-term contracts to ensure market penetration. These companies also largely focus on research and development to gain competitiveness in the market. A detailed analysis of these companies is offered in the report.
Driver: Technological advancement in electronics and miniaturisation
The increasing market demand for field programmable gate arrays is due to its technological advancement, adoption of cloud-based solutions and computation powers, heavy investments in the start-up economy fuelling R&D within the market, and increasing demand for highly technological and advanced products by the end–users to streamline operations. Many companies across the world are currently investing in the FPGA market. Various factors are driving the FPGA market, such as cuts in the cost of production.FPGA has reduced the cost of production by cutting the cost as least hardware resources are required for the process. Second, the high usage of the internet these days is increasing the cloud gaming market, supporting FPGA usage. Internet consumption is increasing day by day, promoting the usage of FPGA . It provides a convenient source through which the consumer can change the hardware as per his need without dissembling the product even after the manufacturing.
Restrain: Limited skilled labour to understand the technology
There are various restraints in the field programmable gate array market. Some factors that are the restraints in the FPGA market and limiting its operations are highly complex programming devices that involve the usage of field array programmable language and are quite complexly programmed for end users to understand if they do not have any technical qualifications. Other than that, there is also a lack of improved and standardized verification techniques required to make the program verifiable to the end –users.
Opportunity: Proliferating demand in emerging economies
The FPGA market shows promising opportunities in the Asia-Pacific region and developed countries of other regions. This is largely observed due to increasing disposable income. Consumers are more inclined towards low-cost and efficient electronic gadgets and internet usage and readily invest in experimenting with new gadgets. It also increases the business opportunities to explore new business verticals using growing technology, and innovations in the IT sector are attracting consumers towards technological advances. There is a rise in internet usage and the technologies that work on the internet. Rising demand for the FPGA in high bandwidth devices for high-end applications. Due to the increase in the deployment of 5G technology and communication structure, there is a lot of scope for eFPGA in the aerospace and defense sector.
Field Programmable Gate Array Market: Recent Developments
- In November 2022, Efinix FPGAs integrated the TinyML platform for AI acceleration.
- In August 2022, Sony Semiconductor selected Efinix FPGA for the HDR camera board.
- In March 2023, Samsung invested in South Korea's mega chip-making plan.
Field programmable gate array Market: Synopsis
The field programmable gate array market study offers revenue and growth data sets of segments provided at the global, regional, and country levels. The report offers the historical data set for 2018-2022 and the forecast period of 2023-2033. For analysis, Quadrant Market Insights (QMI) has segregated the cheese market into four major segments as follows:
By Type
- Field Programmable Gate Array (FPGA)
- Embedded field programmable gate arrays (eFPGAs)
By Nodal Size
- Less than or equal to 16 NM
- 20NM to 90NM
- More than 90NM
By Technology
- Electrically Erasable Programmable Read-only Memory (EEPROM)
- Static Random Access Memory (SRAM)
- FLASH
- Antifuse
- Others
By End Use Industry
- IT and telecom
- Consumer and electronics
- Automotive and Industrial
- Aerospace and defense
The regional analysis of the field programmable gate array (FPGA) market is as follows:
North America
- U.S.
- Canada
- Mexico
Europe
- UK
- Germany
- France
- Russia
- Italy
- Spain
- Rest of Europe
Asia-Pacific
- China
- India
- Japan
- Australia
- Rest of Asia-Pacific
Latin America
- Brazil
- Mexico
- Argentina
- Chile
Middle East & Africa
- South Africa
- UAE
- Saudi Arabia
- Israel
Key players operating in the field programmable gate array (FPGA) industry are:
- Adicsys
- Achronix Semiconductor Corporation
- Efinix Inc.
- Flex Logic Technologies Inc.
- GOWIN Semiconductor Corporation
- Intel Corporation
- Lattice Semiconductor Corporation
- Microchip Technology Limited
- Quick Logic Corporation
- Xilinx, Inc.
field programmable gate array (FPGA) Market: Who Should Purchase, and How It Will Help Readers
- The report is best suited for top-level decision-makers, individuals who are supposed to take a leadership role or require market research to start a business, independent researchers, research institutes, and anyone who wishes to gain detailed strategic insights into the field programmable gate array (FPGA)market.
- This report provides a qualitative and quantitative analysis of the market segments, current trends, estimations, and dynamics of the field programmable gate array (FPGA)market analysis from 2018 to 2033 to identify the prevailing market opportunities.
- Market research and information related to key drivers, restraints, and opportunities are offered.
- Porter's five forces and PESTLE analysis highlight the potency of buyers and suppliers to enable stakeholders' market profit-oriented business decisions and strengthen their supplier-buyer network.
- An in-depth analysis of the field programmable gate array (FPGA)segmentation assists in determining the prevailing market opportunities.
- Major countries in each region are mapped according to their revenue contribution to the global market.
- Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.
- The report includes an analysis of the regional and global field programmable gate array (FPGA)industry trends, key players, market segments, application areas, and market growth strategies.
- The report offers insights from primary interviews and CXOs of major industry players. It also offers a comprehensive contact and event repository to ensure future collaborations among industry stakeholders.
field programmable gate array (FPGA) Market: Frequently Asked Questions (FAQ)
Q: How big is the field programmable gate array (FPGA) market?
A: The global field programmable gate array market showcased a revenue of USD 4.21 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 17.19% over the forecast period of 2023-2033
Q: Does the report have several field programmable gate array (FPGA) numbers bifurcated by segments and regions?
A: The report offers a total number of field programmable gate array (FPGA)market , further bifurcated into segments and regions. Please refer to the TOC page for more information.
Q: What are the major trends in the field programmable gate array (FPGA) market?
A: Proliferation within the internet and technological sector, increase in disposable income in developing regions, and growing awareness of technology and industrial market sector affect market growth of field programmable gate array.
Q: How can I get the sample Report on the field programmable gate array (FPGA) market?
A: The field programmable gate array (FPGA)market report sample can be obtained on demand from the website. Also, 24*7 chat support and direct call services are provided to procure the sample report
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A: Yes, it is possible to purchase a specific part of the report or edit the scope of the report at your convenience. Feel free to drop us the mail/talk to our customer support or schedule a conversation to procure a customized report.
Report Coverage
- Type
- Node Size
- Technology
- End Use Industry
- North America
- Europe
- Asia-Pacific
- Latin America
- Middle East & Africa
- Technological advancements in electronics and miniaturization
- Proliferating demand in emerging economies
- Limited skilled labour to understand technology
Adicycs, Achronix Semiconductor Corporation, Efinix Inc., Flex Logic Technologies, Inc., GOWIN Semiconductor Corporation, Intel Corporation, Lattice Semiconductor Corporation, Microchip Technology Inc., QuickLogic Corporation, Xilinx Inc.
1. Introduction
1.1 Report Description
1.1.1 Definition
1.1.2 Abbreviations
1.2 Key Market Segments
1.3 Benefits to Stakeholders
1.4 Research Methodology
1.4.1 Market Scoping
1.4.1.1 Problem Identification
1.4.1.2 Defining the Market
1.4.2 Market Estimation
1.4.2.1 Data Mining
1.4.2.2 Product Analysis
1.4.2.3 Application Analysis
1.4.2.4 Market Engineering and Forecasting
1.4.2.4.1 Bottom-up Demand Side
1.4.2.4.2 Bottom-up Supply side
1.4.3 Market Authentication
1.4.3.1 Data Triangulation
1.4.3.1.1 Top-down Supply Side
1.4.3.1.2 Top-down Demand Side
1.4.3.1.3 Data Triangulation
1.4.3.2 Primary Insights and Industry feedback
1.4.4 Report Writing
2. Executive Summary
2.1 Market Snapshot
2.2 Macro Trends, Global Economic Factors and Import/Export Insights
2.3 Primary Insights
2.4 Administration Insights
2.5 Form Insights
2.6 Application Insights
2.7 Sales Channel Insights
2.8 Regional Insights
3. Market Overview
3.1 Market Segment and Scope
3.2 Top Investment Pockets
3.3 Key Strategic Initiatives
3.4 Field Programmable Fate Array (FPGA) Market Industry Ecosystem
3.5 Market Evolution
3.6 Patent Analysis
3.7 Technology Landscape
3.8 Regulatory Infrastructure
3.9 Porter’s Analysis
3.9.1 Bargaining Power of Buyer
3.9.2 Bargaining Power of Supplier
3.9.3 Threat of New Entrants
3.9.4 Threat of Substitutes
3.9.5 Industry Rivalry
3.10 PESTLE Analysis
3.11 Market Dynamics
3.11.1 Drivers
3.11.2 Restrains
3.11.3 Opportunities
3.12 Impact of COVID-19 on Field Programmable Gate Array (FPGA)Market
3.13 Russia-Ukraine War Impact on Field Programmable Gate Array (FPGA)Market
3.14 Growth Share Matrix
3.15 Field Programmable Gate Array (FPGA)Market Quadrant
4. Field Programmable Gate Array (FPGA) Market, By Type
4.1 Major Impacting Factors, By Type
4.1.1 Key Market Trends and Growth Factors
4.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
4.2 Field Programmable Gate Array (FPGA)
4.2.1 Key Market Trends and Growth Factors
4.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
4.3 Embedded field programmable gate arrays (eFPGAs)
4.3.1 Key Market Trends and Growth Factors
4.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5. Field Programmable Gate Array (FPGA) Market, By Node Size
5.1 Major Impacting Factors, By Node Size
5.1.1 Key Market Trends and Growth Factors
5.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5.2 Less than or equal to 16NM
5.2.1 Key Market Trends and Growth Factors
5.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5.3 20NM to 90NM
5.3.1 Key Market Trends and Growth Factors
5.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5.4 More than 90NM
5.4.1 Key Market Trends and Growth Factors
5.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6. Field Programmable Gate Array (FPGA) Market, By Technology
6.1 Major Impacting Factors, By Technology
6.1.1 Key Market Trends and Growth Factors
6.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.2 Electrically Erasable Programmable Read-only Memory (EEPROM)
6.2.1 Key Market Trends and Growth Factors
6.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.3 Static Random Access Memory (SRAM)
6.3.1 Key Market Trends and Growth Factors
6.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.4 Flash
6.4.1 Key Market Trends and Growth Factors
6.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.5 Antifuse
6.5.1 Key Market Trends and Growth Factors
6.5.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.5.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.6 Others
6.6.1 Key Market Trends and Growth Factors
6.6.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.6.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7. Field Programmable Gate Array (FPGA) Market, By End Use Industry
7.1 Major Impacting Factors, By End Use Industry
7.1.1 Key Market Trends and Growth Factors
7.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
7.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.2 IT and Telecom
7.2.1 Key Market Trends and Growth Factors
7.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
7.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.3 Consumer Electronics
7.3.1 Key Market Trends and Growth Factors
7.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
7.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.4 Automotive and Industrial
7.4.1 Key Market Trends and Growth Factors
7.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
7.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.5 Aerospace and Defense
7.5.1 Key Market Trends and Growth Factors
7.5.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
7.5.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
8. Field Programmable Gate Array (FPGA) Market, By Region
8.1 Global Market Trends and Growth Factors
8.2 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.3 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.4 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.5 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.6 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
8.7 North America
8.7.1 Key Market Trends and Growth Factors
8.7.2 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.7.3 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.7.4 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.7.5 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.7.6 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
8.7.7 U.S.
8.7.7.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.7.7.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.7.7.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.7.7.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.7.8 Canada
8.7.8.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.7.8.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.7.8.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.7.8.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.7.9 Mexico
8.7.9.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.7.9.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.7.9.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.7.9.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.8 Europe
8.8.1 Key Market Trends and Growth Factors
8.8.2 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.8.3 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.8.4 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.8.5 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.8.6 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
8.8.7 UK
8.8.7.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.8.7.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.8.7.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.8.7.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.8.8 Germany
8.8.8.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.8.8.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.8.8.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.8.8.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.8.9 France
8.8.9.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.8.9.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.8.9.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.8.9.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.8.10 Russia
8.8.10.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.8.10.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.8.10.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.8.10.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.8.11 Italy
8.8.11.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.8.11.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.8.11.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.8.11.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.8.12 Rest of Europe
8.8.12.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.8.12.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.8.12.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.8.12.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.9 Asia-Pacific
8.9.1 Key Market Trends and Growth Factors
8.9.2 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.9.3 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.9.4 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.9.5 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.9.6 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
8.9.7 China
8.9.7.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.9.7.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.9.7.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.9.7.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.9.8 India
8.9.8.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.9.8.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.9.8.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.9.8.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.9.9 Japan
8.9.9.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.9.9.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.9.9.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.9.9.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.9.10 Australia
8.9.10.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.9.10.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.9.10.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.9.10.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.9.11 Rest of Asia-Pacific
8.9.11.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.9.11.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.9.11.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.9.11.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.10 Latin America
8.10.1 Key Market Trends and Growth Factors
8.10.2 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.10.3 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.10.4 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.10.5 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.10.6 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
8.10.7 Brazil
8.10.7.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.10.7.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.10.7.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.10.7.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.10.8 Argentina
8.10.8.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.10.8.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.10.8.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.10.8.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.10.9 Mexico
8.10.9.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.10.9.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.10.9.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.10.9.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.10.10 Chile
8.10.10.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.10.10.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.10.10.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.10.10.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.11 Middle East and Africa
8.11.1 Key Market Trends and Growth Factors
8.11.2 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.11.3 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.11.4 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.11.5 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.11.6 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
8.11.7 South Africa
8.11.7.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.11.7.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.11.7.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.11.7.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.11.8 UAE
8.11.8.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.11.8.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.11.8.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.11.8.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.11.9 Saudi Arabia
8.11.9.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.11.9.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.11.9.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.11.9.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
8.11.10 Israel
8.11.10.1 Market Size and Forecast, by Type, 2017-2032, (USD Billion)
8.11.10.2 Market Size and Forecast, by Node Size, 2017-2032, (USD Billion)
8.11.10.3 Market Size and Forecast, by Technology, 2017-2032, (USD Billion)
8.11.10.4 Market Size and Forecast, by End Use Industry, 2017-2032, (USD Billion)
9. Competitive Benchmarking & Company Profiles
9.1 Competitive Benchmarking
9.1.1 Company Market Share
9.1.2 Product Mapping
9.1.3 Competitive Heat map
9.2 Adicsys
9.2.1 Company Overview
9.2.2 Financial Analysis
9.2.3 Product Offering
9.2.4 Strategic Initiatives
9.2.5 SWOT
9.2.6 Ansoff Matrix
9.3 Achronix Semiconductor Corporation
9.3.1 Company Overview
9.3.2 Financial Analysis
9.3.3 Product Offering
9.3.4 Strategic Initiatives
9.3.5 SWOT
9.3.6 Ansoff Matrix
9.4 Efinix, Inc.
9.4.1 Company Overview
9.4.2 Financial Analysis
9.4.3 Product Offering
9.4.4 Strategic Initiatives
9.4.5 SWOT
9.4.6 Ansoff Matrix
9.5 Flex Logic Technologies, Inc.
9.5.1 Company Overview
9.5.2 Financial Analysis
9.5.3 Product Offering
9.5.4 Strategic Initiatives
9.5.5 SWOT
9.5.6 Ansoff Matrix
9.6 GOWIN Semiconductor Corporation
9.6.1 Company Overview
9.6.2 Financial Analysis
9.6.3 Product Offering
9.6.4 Strategic Initiatives
9.6.5 SWOT
9.6.6 Ansoff Matrix
9.7 Intel Corporation
9.7.1 Company Overview
9.7.2 Financial Analysis
9.7.3 Product Offering
9.7.4 Strategic Initiatives
9.7.5 SWOT
9.7.6 Ansoff Matrix
9.8 Lattice Semiconductor Corporation
9.8.1 Company Overview
9.8.2 Financial Analysis
9.8.3 Product Offering
9.8.4 Strategic Initiatives
9.8.5 SWOT
9.8.6 Ansoff Matrix
9.9 Microchip Technology Inc.
9.9.1 Company Overview
9.9.2 Financial Analysis
9.9.3 Product Offering
9.9.4 Strategic Initiatives
9.9.5 SWOT
9.9.6 Ansoff Matrix
9.10 QuickLogic Corporation
9.10.1 Company Overview
9.10.2 Financial Analysis
9.10.3 Product Offering
9.10.4 Strategic Initiatives
9.10.5 SWOT
9.10.6 Ansoff Matrix
9.11 Victus, Inc.
9.11.1 Company Overview
9.11.2 Financial Analysis
9.11.3 Product Offering
9.11.4 Strategic Initiatives
9.11.5 SWOT
9.11.6 Xilinx, Inc.
10. Industry Connects and Upcoming Seminars
