Global Rad-Tolerant FPGA Market 2022-2030

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    GLOBAL RAD-TOLERANT FPGA MARKET

     

    INTRODUCTION

     

    Radiation-Tolerant Field Programmable Gate Arrays (FPGAs) come in varieties, and some of them are used to implement designs for the harshest radiation environments like space flight, high-altitude aviation, medical electronics, and controlling nuclear power plants.

     

     

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    They utilize the adaptability and user-friendliness of reprogrammable FPGAs to simplify the design of high-speed datapaths within space payloads by combining a fourth-generation Flash-based FPGA fabric with high-performance SerDes and other interfaces on a single chip.

     

    They significantly boost signal processing throughput thanks to their higher performance and significantly increased logic density.

     

    Additionally, they provide resistance to configuration Single Event Upsets (SEUs), and a third type is utilized when the space application demands extreme radiation performance.

     

    SEU-hardened D-type flip-flops in these enhanced versions of commercial SX-A family of devices provide the advantages of Triple Module Redundancy (TMR) without requiring cumbersome user intervention.

     

    GLOBAL RAD-TOLERANT FPGA MARKET  SIZE AND FORECAST

     

    The Global Rad-Tolerant FPGA market accounted for $XX Billion in 2021 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2022 to 2030.

     

    NEW PRODUCT LAUNCH

     

    Designers in these three fields, like everyone else, are under increasing pressure to increase integration and decrease power.At the same time, they are trembling because cell-based ASIC design costs are so high.

     

      Engineering samples of the RTAX4000S wafers are available from Actel.In the first quarter, it plans to provide customer samples of nonhermetic development chips, and flight-qualified chips will be available for shipment.

     

     In addition to the traditional space community, interest in large, radiation-tolerant, and radiation-hardened FPGAs continues to grow in the military and aerospace industries that operate within the atmosphere.

     

    The devices are being examined by networking and telecom infrastructure vendors, who are becoming increasingly concerned about radiation-induced single-event upsets (SEUs).

     

     

    It has been demonstrated that antifuse FPGAs can be manufactured in both rad-tolerant and rad-hard variants.Actel will present its largest rad-tolerant component to date today:the antifuse-based RTAX4000S, whose capacity Actel estimates to be approximately 500 thousand ASIC-gate equivalents.

     

    It has just over 20,000 register bits, each of which is implemented in a triple-redundant voting flip-flop, making it a more useful capacity measurement.

     

    At a linear energy transfer level greater than 37 MeV-cm2/mg, SEU immunity results.The chip is expected to function at a total ionizing dose of 300 kilorads, which is sufficient for applications in the atmosphere and low-Earth orbit as well as for highly elliptical orbits that traverse the Van Allen belts.

     

    Although Actel does not provide hardened RAM cells or built-in error detection and recovery circuitry, the embedded blocks of the device contain 540 kbits of SRAM.

     

    Compact macro The embedded blocks of the device contain 540 kbits of SRAM, but Actel does not provide hardened RAM cells or built-in error recovery circuitry.

     

    To implement a shorter Hamming code, the company offers a very small macro that can be programmed into the hardened logic fabric.This can be used for memory array periodic scrubbing, in-line reads, or both.

     

    The RTAX-S family’s various features also make development easier for users.One is straightforward:Development chips will be offered in packages that are significantly less expensive than the spacecraft’s full-up hermetic ceramics. The chips can be burned in as a novel but equally useful feature after they have been programmed.

     

     

    COMPANY PROFILE

     

    THIS REPORT WILL ANSWER FOLLOWING QUESTIONS

    1. What is the average cost per Global Rad-Tolerant FPGA market right now and how will it change in the next 5-6 years?
    2. Average cost to set up a Global Rad-Tolerant FPGA market in the US, Europe and China?
    3. How many Global Rad-Tolerant FPGA market are manufactured per annum globally? Who are the sub-component suppliers in different regions?
    4. What is happening in the overall public, globally?
    5. Cost breakup of a Global Rad-Tolerant FPGA market and key vendor selection criteria
    6. Where is the Global Rad-Tolerant FPGA market  manufactured? What is the average margin per equipment?
    7. Market share of Global Rad-Tolerant FPGA market manufacturers and their upcoming products
    8. The most important planned Global Rad-Tolerant FPGA market in next 2 years
    9. Details on network of major Global Rad-Tolerant FPGA market and pricing plans
    10. Cost advantage for OEMs who manufacture Global Rad-Tolerant FPGA market in-house
    11. 5 key predictions for next 5 years in Global Rad-Tolerant FPGA market
    12. Average B-2-B Global Rad-Tolerant FPGA market price in all segments
    13. Latest trends in Global Rad-Tolerant FPGA market, by every market segment
    14. The market size (both volume and value) of Global Rad-Tolerant FPGA market in 2022-2030 and every year in between?
    15. Global production breakup of Global Rad-Tolerant FPGA market, by suppliers and their OEM relationship

     

     

     

    Sl no Topic
    1 Market Segmentation
    2 Scope of the report
    3 Abbreviations
    4 Research Methodology
    5 Executive Summary
    6 Introduction
    7 Insights from Industry stakeholders
    8 Cost breakdown of Product by sub-components and average profit margin
    9 Disruptive innovation in the Industry
    10 Technology trends in the Industry
    11 Consumer trends in the industry
    12 Recent Production Milestones
    13 Component Manufacturing in US, EU and China
    14 COVID-19 impact on overall market
    15 COVID-19 impact on Production of components
    16 COVID-19 impact on Point of sale
    17 Market Segmentation, Dynamics and Forecast by Geography, 2022-2030
    18 Market Segmentation, Dynamics and Forecast by Product Type, 2022-2030
    19 Market Segmentation, Dynamics and Forecast by Application, 2022-2030
    20 Market Segmentation, Dynamics and Forecast by End use, 2022-2030
    21 Product installation rate by OEM, 2022
    22 Incline/Decline in Average B-2-B selling price in past 5 years
    23 Competition from substitute products
    24 Gross margin and average profitability of suppliers
    25 New product development in past 12 months
    26 M&A in past 12 months
    27 Growth strategy of leading players
    28 Market share of vendors, 2022
    29 Company Profiles
    30 Unmet needs and opportunity for new suppliers
    31 Conclusion
    32 Appendix

     

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