Dublin, June 15, 2022 (GLOBE NEWSWIRE)-Radiation-Resistant Electronics for the Space Applications Market-Global and Regional Analysis: Focusing on Platforms, Manufacturing Techniques, Material Types, Components, and Countries-Analysis and Forecast , 2022- 2032 “Report added to ResearchAndMarkets.com Recruitment.
Global radiation-resistant electronics for the space application market are estimated to grow at 1.70% over the forecast period, from $ 2,348 million in 2021 to $ 4,761.1 million in 2032. ..
The growth of global radiation-resistant electrical equipment for the space application market is expected to be driven by increasing demand for communications and earth observation satellites.
Market life cycle stage
Over the last few years, there has been a dramatic shift towards adopting smaller satellites than traditional satellites. In addition, the market is witnessing a drift towards normal use in satellite constellations as it uses small satellites for temporary stints. With the rapid growth of small satellite constellations for a variety of applications such as earth observation, remote sensing, and space-based broadband services, the demand for radiation-resistant electronic components has also increased significantly.
Several projects are currently underway to manufacture highly radiation-resistant electrical devices with enhanced ability to shield space perturbations at low cost. It can last for a long time in a harsh space environment.
The various radiation-curing electronics currently in use include on-board computers, microcontrollers and microcontrollers, power supplies, memory (solid state recorders), field programmable gate arrays, transmitters and receivers (antennas), and application-specific integrations. Circuits and sensors. .. Space is a huge market with endless opportunities and requires radiation resistant components on all platforms to function. As a result, the market for radiation-resistant electrical devices for space applications is well established.
The increase in low earth orbit (LEO) satellites associated with future megaconstellation creates a high demand for the production of space-based radiation-resistant components that can withstand the high radiation effects caused by solar flares.
In addition, the growing interest of space agencies in long-term missions requires radiation-resistant components that can be compressed or miniaturized to withstand harsh environments while supporting complex missions for significantly longer periods of time.
Platform (satellite, rocket, deep space probe)
Based on the platform, global radiation-resistant electronics for the space application market in the platform segment are expected to be dominated by satellite platforms.
Manufacturing technology (radiation resistance by design, radiation resistance by process, radiation resistance by software)
Based on manufacturing technology, global radiation resistant electronics for the space applications market are slightly dominated by radiation resistance by the design segment. Although the radiation-resistant manufacturing techniques by design are expensive to manufacture, the components provide a very robust solution and the highest radiation resistance that can be used in extreme space applications such as deep space missions and satellites.
Material type (silicon, gallium nitride, silicon carbide, etc.)
Most of the radiation resistant components are made of silicon. This is to help reduce size and weight and improve computational performance from medium to high speeds.
Components (onboard computers, microprocessors, controllers, power supplies, memory (solid state recorders), field programmable gate arrays, transmitters and receivers (antennas), application-specific integrated circuits, sensors)
Due to technological advances, onboard computers, microprocessors, and controllers are expected to be used in new applications that require more efficient, robust, and high-performance microprocessor technology, resulting in more advanced and demanding. Deploys tougher applications in smaller spaces.
Overview of major market players and competition
The companies to be profiled are selected based on inputs collected from key experts and an analysis of the company’s coverage, product portfolio, and market penetration.
The market-leading top segment players include established players that provide radiation-resistant electrical equipment for space applications, making up 80% of the market presence. Other players include start-ups, which account for about 20% of their market presence.
Recent developments in global radiation resistant electrical devices for the space applications market
- In June 2020, GSI Technology partnered with the Space NSF Center to build a cost-effective modular computer system for space-related efforts, from ground-based high-performance computing data centers to deep space missions. Did.
- In March 2021, Mercury Systems signed a contract with NASA’s Jet Propulsion Laboratory to provide solid-state data recorders for scientific missions. This device will be installed in the Earth Imaging Spectrometer, which is scheduled to be launched in 2022.
- In August 2021, STMicroelectronics worked with Xilinx to build a power supply solution for Xilinx Radiation Resistant Field Programmable Gate Arrays (FPGAs) with a QML-V certified voltage regulator.
- In April 2021, Exxelia launched a high-performance space resistor that meets the requirements of weapon platforms, modern electronic warfare, and a wide range of space applications.
Some of the prominent names established in this market are:
- 3D plus
- Analog Devices
- Aposi Semiconductor
- Cobham Plc
- Data Device Co., Ltd.
- General Dynamics
- GSI Technology, Inc.
- Infineon Technologies
- Mercury Systems, Inc.
- Microchip Technology, Inc.
- Micropac Industries
- Renesas Electronics Corporation
- Solid State Devices, Inc.
- STMicroelectronics NV
- Teledyne Technologies
- Texas Instruments
- Vorago Technologies
- Xilinx, Inc.
Other key players
- TE Connectivity
Main topics to cover:
1.1 Industry outlook
1.1.1 Radiation-resistant electrical equipment for the space applications market: Overview
184.108.40.206 New Space: New Business Opportunities from LEO-Focused Small Satellites and Deep Space Missions
1.1.2 Comparison of standard requirements for radiation resistant products (by end user)
1.1.3 Continuing radiation resistance efforts in the space industry
220.127.116.11 Davinci +
18.104.22.168 February ice cubes
22.214.171.124 Jupiter Icy Moons Explorer (JUICE)
126.96.36.199 Peregrine Mission 1
1.1.4 Current and future trends
188.8.131.52 Machine learning with space-grade FPGAs
184.108.40.206 Single board computer for space missions
220.127.116.11 Artificial intelligence based ARM quad-core processor
18.104.22.168 Radiation resistant plastic package integrated circuit
22.214.171.124 Complementary metal oxide film semiconductor image sensor
1.1.5 Certified as a radiation resistant electronic device manufacturer
1.1.6 Supply chain analysis
1.2 Business Dynamics
1.2.1 Business driver
126.96.36.199 Increasing demand for radiation resistant electronic components in the communications satellite segment
188.8.131.52 Technological advances in microprocessors and FPGAs
1.2.2 Business challenges
184.108.40.206 High cost development and design related to radiation resistant electronic components
220.127.116.11 Impact of shortage of electronic components on the global space industry
1.2.3 Business Strategy
18.104.22.168 Launch of new product
1.2.4 Corporate Strategy
22.214.171.124 Partnerships, collaborations, contracts, and contracts
126.96.36.199 Mergers and acquisitions
1.2.5 Business Opportunity
188.8.131.52 Adoption of new materials for manufacturing space electronics
2.1 Global Radiation Resistant Electronics for the Space Applications Market-By Platform
2.1.1 Market Overview
184.108.40.206 Demand analysis of radiation-resistant electronic devices for the space application market (by platform)
220.127.116.11 Small satellite (0-500Kg)
18.104.22.168 Medium satellite (501-1,000Kg)
22.214.171.124 Large satellite (1,001Kg or more)
126.96.36.199.1 Demand analysis of satellite market
188.8.131.52 Small and medium rocket
184.108.40.206 Heavy lift rocket
220.127.116.11.1 Rocket market demand analysis
2.1.4 Deep space probe
3.1 Global Radiation Resistant Electronics for Space Applications Market-By Manufacturing Technology
3.1.1 Market Overview
18.104.22.168 Demand analysis of radiation-resistant electronic devices for the space application market (based on manufacturing technology)
3.1.2 Radiation resistant design
22.214.171.124 Total ionized dose
126.96.36.199 Single event effect
Radiation resistance by 3.1.3 process
188.8.131.52 Silicon on insulator
184.108.40.206 Silicon on sapphire
3.1.4 Software radiation resistance
3.2 Global Radiation Resistant Electronics for the Space Applications Market-By Material Type
3.2.1 Market overview
220.127.116.11 Demand analysis of radiation-resistant electronic devices for the space application market (by material type)
3.2.3 Gallium nitride
3.2.4 Silicon Carbide
3.3 Global Radiation Resistant Electronics for the Space Applications Market-By Component
3.3.1 Market Overview
18.104.22.168 Demand analysis of radiation-resistant electronic devices for the space application market (by component)
3.3.2 Onboard computers, microprocessors, and controllers
3.3.3 Power supply (power management device, solar panel, battery, converter)
3.3.4 Memory (Solid State Recorder)
3.3.5 Field Programmable Gate Array (FPGA)
3.3.6 Transmitter and receiver (antenna)
3.3.7 Integrated circuits for specific applications
4.1 Global radiation-resistant electronic devices for the space applications market (by region)
5 Markets-Market Share Analysis and Company Profile
5.1 Market Share Analysis
5.2 Company profile
5.2.1 Role in radiation-resistant electrical equipment for the space applications market
5.2.2 Product portfolio
5.3 Business Strategy
5.3.1 Launch of new products
6 Growth opportunities and recommendations
6.1 Growth Opportunities
7 Survey method
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Radiation resistant electronics for the space applications market