嵌入式 FPGA（现场可程式闸阵列）市场规模（按架构、技术节点、应用、地区、范围和预测）

嵌入式 FPGA（现场可程式闸阵列）市场规模及预测

嵌入式 FPGA（现场可程式闸阵列）市场规模预计在 2023 年达到 115.9 亿美元，2024 年至 2030 年的复合年增长率为 10.8%。

嵌入式 FPGA（现场可程式闸阵列）的全球市场推动因素

嵌入式 FPGA（现场可程式闸阵列）市场的市场推动因素会受到多种因素的影响。

对客製化和灵活性的需求日益增加：

嵌入式 FPGA 具有高度可自订性和灵活性，可让设计人员融入特定功能或适应不断发展的规格。这促使各行各业对嵌入式 FPGA 解决方案的需求日益增长。

半导体设计的复杂度不断增加：

嵌入式 FPGA 被用来解决日益复杂的半导体设计所带来的课题，例如平行处理、特定演算法的加速以及在单一晶片上整合多种功能的需求。

改善网路和通讯：

嵌入式 FPGA 经常用于网路和通讯设备，提供资料包过滤、协定处理和加密加速等功能。嵌入式 FPGA 市场正因高效能网路解决方案的需求而不断扩大。

5G技术的出现：

5G 网路的推出推动了基地台和其他网路基础设施硬体对嵌入式 FPGA 的需求。 FPGA 的多功能性允许快速升级和修改，以满足 5G 不断变化的需求和标准。

汽车电子：

在汽车电子领域，嵌入式 FPGA 用于影像处理、感测器融合和车载网路等活动。嵌入式 FPGA 技术的使用是由自动驾驶的发展和车载系统日益复杂所驱动。

物联网 (IoT) 的兴起：

随着生态系统的扩展，嵌入式 FPGA 正用于实现边缘运算功能、感测器介面和客製化加速器，平衡物联网设备的效率和灵活性。

对节能解决方案的需求：

由于嵌入式 FPGA 具有可扩展的功率效率，电池供电和能源受限的设备可以从中受益。人们对电子产品能源效率的日益重视，推动了嵌入式 FPGA 解决方案的普及。

在人工智慧和机器学习应用中的使用日益增加：

神经网路推理加速是嵌入式 FPGA 在 AI 和机器学习应用中的使用活动之一。 FPGA 的平行处理能力使其成为某些 AI 任务的理想选择。

上市时间与快速原型设计：

嵌入式 FPGA 可实现半导体设计的快速上市和快速原型製作。嵌入式 FPGA 系统很有吸引力，因为它们允许设计人员在硬体实现之后对其进行修改和扩展。

FPGA技术开发：

嵌入式 FPGA 的广泛扩展和使用是由 FPGA 技术的不断发展所推动的，包括製程节点、容量和功率效率的改进。

限制全球嵌入式 FPGA 市场的因素

嵌入式 FPGA 市场存在一些限制与课题。

开发成本高：

在设计和开发嵌入式 FPGA 系统时，前期成本，尤其是研发成本，可能非常高。对于预算有限的新创公司和小型企业来说，这可能是一个障碍。

复杂性与专业知识的需求：

硬体设计和 FPGA 程式设计是需要特定知识和经验来实现嵌入式 FPGA 解决方案的学科。缺乏熟练工程人才的公司可能会因为这些技术的复杂性而难以实施这些技术。

标准化程度有限：

缺乏标准化的介面或架构可能导致相容性问题和与目前系统整合的困难。这可能会导致更高的成本和更长的开发时间。

电力问题：

FPGA 提供灵活的硬体加速，但比其他选项或专门的专用积体电路 (ASIC) 消耗更多的能量。电源效率是许多应用中的关键因素，例如物联网设备和电池供电系统。

上市时间：

设计和实施嵌入式 FPGA 解决方案所需的时间可能与某些公司的快速产品开发週期不一致。对于技术快速发展的行业中的公司来说，满足产品上市时间的需求可能是一个课题。

与替代技术的衝突：

ASIC、GPU 以及日益强大的微处理器是 FPGA 必须与之竞争的一些替代技术。根据特定应用的需求，这些替代技术可能会取代 FPGA，进而影响市场成长。

安全性问题：

在安全关键型应用中，FPGA 设计中的弱点令人担忧。由于嵌入式 FPGA 中的可重编程逻辑需要保证安全性，因此其在敏感产业的应用可能会因危险认知而受到限制。

最终使用者认知有限：

有些公司可能不太瞭解或不理解嵌入式 FPGA 的优势。向使用者告知这项技术的优势和应用对于促进其广泛采用至关重要。

供应链中断：

嵌入式 FPGA 製造所需组件的可用性可能会受到全球供应链环境变化的影响。嵌入式 FPGA 产业的公司可能会因地缘政治问题和半导体材料短缺等因素而面临课题。

目录

第 1 章简介

• 市场定义
• 市场区隔
• 研究方法

第 2 章执行摘要

• 主要发现 市场概况
• 市场亮点

第3章 市场概览

• 市场规模与成长潜力
• 市场趋势
• 市场推动因素
• 市场限制
• 市场机会
• 波特五力分析

第 4 章 嵌入式 FPGA 市场（依架构）

• 基于 SRAM 的 FPGA
• 以反熔丝为基础的 FPGA
• 基于快闪记忆体的 FPGA

第 5 章 嵌入式 FPGA 市场（依技术节点）

• 90nm 及以下
• 65nm、45nm、28nm等。

第 6 章：嵌入式 FPGA 市场（按应用）

• 通讯与网路
• 消费性电子产品
• 汽车
• 工业 航空航太和国防
• 医疗
• IoT（物联网）

第 7 章 区域分析

• 北美洲
• 美国
• 加拿大
• 墨西哥
• 欧洲
• 英国
• 德国
• 法国
• 义大利 亚太地区
• 中国
• 日本
• 印度
• 澳大利亚
• 拉丁美洲
• 巴西
• 阿根廷
• 智利
• 中东和非洲
• 南非
• 沙乌地阿拉伯
• 阿拉伯联合大公国

第 8 章 市场动态

• 市场推动因素
• 市场限制
• 市场机会
• COVID-19 市场影响

第 9 章 竞争格局

• 大型公司
• 市占率分析

第10章 公司简介

• Intel Corporation
• Xilinx, Inc.
• Qualcomm Technologies, Inc.
• NVIDIA Corporation
• Broadcom Inc.
• AMD, Inc.
• Quicklogic Corporation
• Lattice Semiconductor Corporation
• Achronix Semiconductor Corporation
• Microchip Technology Inc.
• Efinix, Inc.
• Flex Logix Technologies, Inc.
• Menta, Inc.

第 11 章 市场展望与机会

• 新兴技术
• 未来市场趋势
• 投资机会

第 12 章附录

• 缩写列表
• 来源与参考文献

Embedded Field-Programmable Gate Array (FPGA) Market Size And Forecast

Embedded Field-Programmable Gate Array (FPGA) Market size was valued at USD 11.59 Billion in 2023 and is projected to reach USD 21.44 Billion by 2030 , growing at a CAGR of 10.8% during the forecast period 2024-2030.

Global Embedded Field-Programmable Gate Array (FPGA) Market Drivers

The market drivers for the Embedded Field-Programmable Gate Array (FPGA) Market can be influenced by various factors. These may include:

Growing Need for customisation and Flexibility:

Embedded FPGAs offer a great degree of customisation and flexibility, enabling designers to incorporate certain features and adjust to evolving specifications. This has increased the need for embedded FPGA solutions across a range of industries.

Increasing Complexity of Semiconductor Designs:

Embedded FPGA has been adopted to address the challenges posed by the growing complexity of semiconductor designs, which include the need for parallel processing, the acceleration of particular algorithms, and the integration of multiple functions on a single chip.

Improvements in Networking and Telecommunications:

Embedded FPGAs are frequently utilized in networking and telecommunications equipment to provide functions including packet filtering, protocol processing, and encryption acceleration. The market for embedded FPGA has expanded in response to the need for high-performance networking solutions.

5G Technology Emergence:

As 5G networks are deployed, there is a greater need for embedded FPGAs in base stations and other network infrastructure hardware. FPGAs' versatility makes it possible to quickly upgrade and modify them in order to meet the changing needs and standards of 5G.

Automotive Electronics:

Embedded FPGAs are used in image processing, sensor fusion, and in-car networking, among other activities, in automotive electronics. The use of embedded FPGA technology has been aided by the drive toward autonomous driving and the growing complexity of automotive systems.

Increase in IoT (Internet of Things):

Embedded FPGAs are utilized to implement edge computing capabilities, sensor interfaces, and custom accelerators, balancing the efficiency and flexibility of IoT devices as the ecosystem grows.

Demand for Energy-Efficient Solutions:

Battery-powered and energy-constrained devices can benefit from embedded FPGAs since they can be tuned for power efficiency. The acceptance of embedded FPGA solutions has been fueled by the emphasis on energy efficiency in electrical products.

Increasing Use in AI and Machine Learning Applications:

Neural network inference acceleration is one of the activities that embedded FPGAs are used for in AI and machine learning applications. FPGAs are ideally suited for specific AI tasks due to their capacity for parallel processing.

Time-to-Market and Fast Prototyping:

Embedded FPGAs let semiconductor designs reach the market quickly and prototype quickly. Embedded FPGA systems are appealing because they allow designers to make changes and enhancements even after the hardware has been implemented.

Developments in FPGA Technology:

The general expansion and use of embedded FPGAs is facilitated by continuous developments in FPGA technology, which include enhancements in process nodes, capacity, and power efficiency.

Global Embedded Field-Programmable Gate Array (FPGA) Market Restraints

Several factors can act as restraints or challenges for the Embedded Field-Programmable Gate Array (FPGA) Market. These may include:

High Development Costs:

Research and development costs, among other upfront costs, can be substantial when designing and creating embedded FPGA systems. For startups or smaller businesses with tighter budgets, this could be a barrier.

Complexity and Expertise Requirements:

Hardware design and FPGA programming are areas where specific knowledge and experience are needed for the implementation of embedded FPGA solutions. Companies without access to competent engineers may find it difficult to implement these technologies due to their complexity.

Limited Standardization:

Compatibility problems and difficulties integrating embedded FPGAs into current systems may arise from the absence of standardized interfaces and architectures for these devices. Costs may go up and development timelines may take longer as a result.

Concerns About Power Consumption:

Although FPGAs provide flexible hardware acceleration, they could use more energy than other options or specialized application-specific integrated circuits (ASICs). In numerous applications, including Internet of Things devices and battery-powered systems, power efficiency is a crucial factor.

Time-to-Market Pressures:

The length of time needed to design and execute embedded FPGA solutions may not coincide with the quick product development cycles of some businesses. It may be difficult for businesses in industries where technology is advancing quickly to stay up with the demands of the time-to-market.

Competition from Alternative Technologies:

ASICs, GPUs, and ever-more-powerful microprocessors are some of the alternatives that FPGAs must contend with. These alternatives might be chosen over FPGAs depending on the particular application needs, which would affect market growth.

Security Concerns:

There may be worries regarding possible weaknesses in FPGA designs in applications where security is crucial. Adoption in sensitive industries may be restricted by perceived dangers, as reprogrammable logic in embedded FPGAs needs to be secured.

Limited End-User Awareness:

The advantages of embedded FPGAs may not be well known or understood in some businesses. It could be essential to inform prospective users about the benefits and uses of this technology in order to encourage wider adoption.

Supply Chain Disruptions:

The availability of components needed for embedded FPGA manufacture may be impacted by changes in the global supply chain environment. Companies in the embedded FPGA industry may face difficulties as a result of disruptions such as geopolitical issues or shortages in semiconductor materials.

Global Embedded Field-Programmable Gate Array (FPGA) Market Segmentation Analysis

The Global Embedded Field-Programmable Gate Array (FPGA) Market is Segmented on the basis of Architecture, Technology Node, Application, and Geography.

Embedded Field-Programmable Gate Array (FPGA) Market, By Architecture

• SRAM-Based FPGA:
• Utilizes Static Random-Access Memory (SRAM) cells for configuration, offering flexibility and fast reprogramming.
• Antifuse-Based FPGA:
• Utilizes antifuse technology for configuration, providing lower power consumption and resistance to radiation.
• Flash-Based FPGA:
• Configurable using flash memory, offering non-volatile configuration and lower power consumption.

Embedded Field-Programmable Gate Array (FPGA) Market, By Technology Node

90nm and Below:

• Represents FPGA devices manufactured with process technologies of 90 nanometers or smaller, offering higher integration and performance.

65nm, 45nm, 28nm, etc.:

• Denotes specific technology nodes for FPGA manufacturing, with each node representing a different level of miniaturization and efficiency.

Embedded Field-Programmable Gate Array (FPGA) Market, By Application

• Communication and Networking:
• FPGA used in networking equipment, routers, switches, and communication infrastructure for signal processing and packet handling.
• Consumer Electronics:
• Embedded FPGA in devices such as smart TVs, set-top boxes, and gaming consoles for accelerating multimedia processing and enhancing functionality.
• Automotive:
• Employed in automotive applications for advanced driver-assistance systems (ADAS), infotainment, and in-vehicle networking.
• Industrial:
• Used in industrial automation, control systems, and robotics for real-time processing and control.
• Aerospace and Defense:
• FPGA applied in defense systems, radar, avionics, and space applications for signal processing and mission-critical tasks.
• Medical:
• Utilized in medical imaging devices, diagnostic equipment, and healthcare applications for data processing and analysis.
• IoT (Internet of Things):
• FPGA integrated into IoT devices for sensor data processing, connectivity, and edge computing.

Embedded Field-Programmable Gate Array (FPGA) Market, By Geography

• North America:
• Market conditions and demand in the United States, Canada, and Mexico.
• Europe:
• Analysis of the Embedded Field-Programmable Gate Array (FPGA) Market in European countries.
• Asia-Pacific:
• Focusing on countries like China, India, Japan, South Korea, and others.
• Middle East and Africa:
• Examining market dynamics in the Middle East and African regions.
• Latin America:
• Covering market trends and developments in countries across Latin America.

Key Players

• The major players in the Embedded Field-Programmable Gate Array (FPGA) Market are:
• Intel Corporation
• Xilinx, Inc.
• Qualcomm Technologies, Inc.
• NVIDIA Corporation
• Broadcom Inc.
• AMD, Inc.
• Quicklogic Corporation
• Lattice Semiconductor Corporation
• Achronix Semiconductor Corporation
• Microchip Technology Inc.
• Efinix, Inc.
• Flex Logix Technologies, Inc.
• Menta, Inc.

TABLE OF CONTENTS

1. Introduction

• Market Definition
• Market Segmentation
• Research Methodology

2. Executive Summary

• Key Findings
• Market Overview
• Market Highlights

3. Market Overview

• Market Size and Growth Potential
• Market Trends
• Market Drivers
• Market Restraints
• Market Opportunities
• Porter's Five Forces Analysis

4. Embedded Field-Programmable Gate Array (FPGA) Market, By Architecture

• SRAM-Based FPGA
• Antifuse-Based FPGA
• Flash-Based FPGA

5. Embedded Field-Programmable Gate Array (FPGA) Market, By Technology Node

• 90nm and Below
• 65nm, 45nm, 28nm, etc.

6. Embedded Field-Programmable Gate Array (FPGA) Market, By Application

• Communication and Networking
• Consumer Electronics
• Automotive
• Industrial
• Aerospace and Defense
• Medical
• IoT (Internet of Things)

7. Regional Analysis

• North America
• United States
• Canada
• Mexico
• Europe
• United Kingdom
• Germany
• France
• Italy
• Asia-Pacific
• China
• Japan
• India
• Australia
• Latin America
• Brazil
• Argentina
• Chile
• Middle East and Africa
• South Africa
• Saudi Arabia
• UAE

8. Market Dynamics

• Market Drivers
• Market Restraints
• Market Opportunities
• Impact of COVID-19 on the Market

9. Competitive Landscape

• Key Players
• Market Share Analysis

10. Company Profiles

• Intel Corporation
• Xilinx, Inc.
• Qualcomm Technologies, Inc.
• NVIDIA Corporation
• Broadcom Inc.
• AMD, Inc.
• Quicklogic Corporation
• Lattice Semiconductor Corporation
• Achronix Semiconductor Corporation
• Microchip Technology Inc.
• Efinix, Inc.
• Flex Logix Technologies, Inc.
• Menta, Inc.

11. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

12. Appendix

• List of Abbreviations
• Sources and References