Global Fpga in Telecom Market Research Report 2023-Competitive Analysis, Status and Outlook by Type, Downstream Industry, and Geography, Forecast to 2029

Global Fpga in Telecom Market Research Report 2023-Competitive Analysis, Status and Outlook by Type, Downstream Industry, and Geography, Forecast to 2029

The Field-programmable gate array (FPGA) is an application-specific integrated circuit that is supposed to implement logical functions. To implement custom hardware functionality, the field-programmable gate array uses pre-built programmable routing channels and pre-built logic blocks that ultimately depend upon the system developer. With the help of Hardware Description Language (HDL) such as Verilog and VHDL, a field-programmable gate array is programmed. FGPA is designed to be programmed by customer after manufacturing and have numerous applications within telecom such as optical transport network, packet switching and processing.

Market Overview:

The latest research study on the global Fpga in Telecom market finds that the global Fpga in Telecom market reached a value of USD 1703.11 million in 2022. It’s expected that the market will achieve USD 221.57 million by 2028, exhibiting a CAGR of -28.82% during the forecast period.

Severe disruptions to global markets caused by Russia’s war on Ukraine have exposed vulnerabilities to the security of the supply of raw materials critical for industrial production and for the green transition. The Russia-Ukraine war has the potential to exacerbate FPGA supply chain issues and the chip shortage that has impacted the industry for the past two years. These supply chain vulnerabilities are the result of export restrictions, bilateral dependencies, a lack of transparency and persistent market asymmetries, including the concentration of production in just a few countries. For countries affected by supply chain vulnerabilities, there is potential to diversify sourcing through expanded production and accessing known critical raw materials reserves. A collective and coordinated approach among OECD countries can contribute to economic security, while preserving the benefits of open markets and a rules-based international trading system.

Growing demand form telecom industry

In the telecom system, there is a huge need for a field-programmable gate array and its feature of proprietary functionality helps in rising the application of FPGA in the telecom sector. The increasing demand for field-programmable gate array in the FPGA in Telecom Sector Market. It is mainly used in applications which has networking and telecom system like an optical transport network.

Powerful function and benefits of FPGA in telecom

As compared to the other modern microprocessors, FPGA allows higher processing speed and power that gives better response times that further leads to improvement in overall performance. FPGA in Telecom Market can be reused and reprogrammed which makes it more flexible and reliable to use in the telecom sector. One can easily modify it and can use it to create prototypes according to the need of the requirements.

High technical barriers

FPGA is an industry with high technical barriers. Different from general IC design enterprises, FPGA companies usually need to develop EDA software suitable for their own hardware. Because of the complexity of FPGA layout and wiring, it is difficult to design hardware, and with the collaborative development of software and hardware, the difficulty of system engineering is upgraded.

High power consumption

Power is a crucial component in the designer’s decision-making process. FPGAs are a popular choice in numerous system designs. A wise selection of FPGAs can significantly aid the designer in reducing the challenges associated with power consumption.

Increase in demand for FPGA security due to telecommunication industry

The telecommunications industry is one of the most promising, with high demand for FPGAs. The global telecom business is rising due to increased investments and developments in communication infrastructure in both developed and developing countries. IoT, Al, and edge computing technologies are driving a paradigm shift in customer needs and preferences, and they are presenting both opportunities and difficulties for telecoms firms.

5G brings opportunities to the industry

Next generation communication relies on standardized protocols, heterogeneous architectures and advanced technologies that are envisioned to bring ubiquitous and seamless connectivity. This evolution of communication will not only improve the performance of the existing networks but will also enables various applications in other fields while integrating different heterogeneous systems.

Region Overview:

In global comparison, a significant portion of the revenue was generated in China (35.49% in 2021).

Company Overview:

Xilinx

Xilinx is the inventor of the FPGA, programmable SoCs, and now, the ACAP. Xilinx, Inc. is an American technology company that is primarily a supplier of programmable logic devices. The company invented the field-programmable gate array (FPGA). It is the semiconductor company that created the first fabless manufacturing model. AMD announced its acquisition of Xilinx in October 2020.

Intel Corporation

Intel Corporation is an American multinational corporation and technology company headquartered in Santa Clara, California, in Silicon Valley. Intel supplies microprocessors for computer system manufacturers such as Lenovo, HP, and Dell. Intel also manufactures motherboard chipsets, network interface controllers and integrated circuits, flash memory, graphics chips, embedded processors and other devices related to communications and computing.

Xilinx is one of the major players operating in the Fpga in Telecom market, holding a share of 43.51% in 2022.

Segmentation Overview:

SRAM programming involves a small static RAM bit for each programming element. Writing the bit with a zero turns off a switch, while writing with a one turns on a switch. Another method involves an antifuse that consists of a microscopic structure that, unlike a regular fuse, normally makes no connection. A large amount of current during programming of the device causes the two sides of the antifuse to connect. A third and relatively new method uses flash EPROM bits for each programming element. The advantages of SRAM-based FPGAs – the most common programming technology by far – is that they use a standard fabrication process that chip fabrication plants are always optimizing for better performance. Since the SRAMs are reprogrammable, the FPGAs can be reprogrammed any number of times, even while they are in the system, just like writing to a normal SRAM. SRAM devices can easily use the internal SRAMs as small memories in the design.

The advantages of antifuse FPGAs are that they are non-volatile and the delays due to routing are very small, so they tend to be faster. Antifuse FPGAs tend to require lower power and they are better for keeping your design information out of the hands of competitors because they do not require an external device to program them upon power-up as SRAM devices do. The disadvantages are that they require a complex fabrication process, they require an external programmer to program them, and once they are programmed, they cannot be changed.

The Electrically Erasable Programmable Read-Only Memory (EEPROM)-based FPGAs are likely to witness sluggish growth over the forecast period owing to rapid increase in usage of newer technologies such as SRAM and Flash. The slow growth over the next few years could be attributed to unceasing improvements in the new technologies, which are nonvolatile in nature, more flexible with respect to application requirements, and less power consuming.

Among different product types, SRAM Programmed FPGA segment is anticipated to contribute the largest market share in 2027.

Application Overview:

The commercial sector accounted for the largest revenue share in 2021 and is anticipated to maintain its dominance over the forecast period. Vast usage of field programmable gate arrays in wireless communication and telecommunication sectors for several applications such as data packet switching, packet processing, and optical transport network is propelling the FPGA market growth.

The defense/aerospace segment is expected to grow at a substantial rate over the forecast period. Emergence of embedded field programmable gate array has particularly favored the defense/aerospace industry by offering even better integration, reliability, and low power option over the traditional FPGAs. FPGA manufacturers are innovating and developing state-of-the-art products for the growing need of this sector.

Key Companies in the global Fpga in Telecom market covered in Chapter 3:

Intel Corporation
Microchip Technology
Xilinx Inc.
Lattice Semiconductor
Achronix

In Chapter 4 and Chapter 14.2, on the basis of types, the Fpga in Telecom market from 2018 to 2029 is primarily split into:

SRAM Programmed FPGA
Antifuse Programmed FPGA
EEPROM Programmed FPGA

In Chapter 5 and Chapter 14.3, on the basis of Downstream Industry, the Fpga in Telecom market from 2018 to 2029 covers:

Commercial
Defense/Aerospace
Others

Geographically, the detailed analysis of consumption, revenue, market share and growth rate, historic and forecast (2018-2029) of the following regions are covered in Chapter 8 to Chapter 14:

North America (United States, Canada)
Europe (Germany, UK, France, Italy, Spain, Russia, Netherlands, Turkey, Switzerland, Sweden)
Asia Pacific (China, Japan, South Korea, Australia, India, Indonesia, Philippines, Malaysia)
Latin America (Brazil, Mexico, Argentina)
Middle East & Africa (Saudi Arabia, UAE, Egypt, South Africa)