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市场调查报告书
商品编码
1936211

功能安全微控制器 (MCU) 市场规模、占有率及预测:依 ASIL 等级(A、B、C、D)、核心架构、週边和软体支援 (AUTOSAR) 划分 - 全球预测 (2026-2036)

Functional Safety Microcontrollers (MCUs) Market Size, Share, & Forecast by ASIL Level (A, B, C, D), Core Architecture, Peripherals, and Software Support (AUTOSAR)- Global Forecast (2026-2036)
出版日期: | 出版商: Meticulous Research | 英文 261 Pages | 商品交期: 5-7个工作天内

价格
简介目录
预计功能安全微控制器市场将以 11.6% 的复合年增长率 (CAGR) 从 2026 年成长至 2036 年,到 2036 年达到 147.3 亿美元。本报告对五大主要地区的功能安全微控制器市场进行了详细分析,重点关注当前市场趋势、市场规模、近期发展以及 2036 年的预测。透过广泛的二级和一级研究以及对市场现状的深入分析,我们对主要行业驱动因素、限制因素、机会和挑战进行了影响分析。市场成长的驱动因素包括:严格的汽车安全法规(ISO 26262)、高端汽车製造商部署先进安全系统的强大影响力、根深蒂固的汽车安全文化对ISO 26262合规性的要求、汽车产量的快速增长、ADAS和自动驾驶技术的日益普及、电动汽车市场对安全认证控制系统的需求不断增长,以及新兴汽车市场安全意识的提升。此外,先进硬体级安全功能的整合、用于同步运行的冗余处理核心的开发、内建自诊断(BiST)功能的应用、对安全监视器和看门狗的日益重视,以及对故障安全状态管理需求的不断增长,预计也将推动市场成长。

目录

第一章:引言

第二章:研究方法

第三章:摘要整理

  • 依ASIL等级划分的市场分析
  • 以核心架构划分的市场分析
  • 依週边设备划分的市场分析
  • 依软体支援划分的市场分析
  • 依应用划分的市场分析
  • 依地区划分的市场分析
  • 竞争分析

第四章:市场洞察

  • 市场驱动因素
    • 自动驾驶和高级驾驶辅助系统 (ADAS) 的普及
    • 电动车的电气化和线控系统
    • 严格的汽车安全标准和 ISO 26262合规性
  • 市场限制
    • 高昂的开发和认证成本
    • 漫长的认证和设计实施週期
  • 市场机遇
    • 功能安全与人工智慧加速的整合
    • 与网域控制器和区域控制器的整合
  • 市场挑战
    • 平衡性能要求和安全认证
    • 管理混合关键性系统中的复杂性
  • 市场趋势
    • 向异质安全架构演进
    • 网路安全与功能安全的整合
  • 波特五力分析

第5章 ISO 26262 和汽车功能安全标准

  • ASIL 分类与要求
  • 安全生命週期以及开发流程
  • 硬体安全需求和指标
  • 软体安全要求
  • 安全案例与认证流程
  • 自动驾驶汽车新标准
  • 区域监理差异
  • 对市场成长与科技应用的影响

第六章:竞争格局

  • 关键成长策略
    • 市场差异化因素
    • 协同效应分析:关键交易与策略联盟
  • 竞争概览
    • 行业领导者
    • 市场差异化因素
    • 先驱者
    • 新兴公司
  • 供应商市场定位
  • 主要公司的市占率和排名

第7章 全球功能安全微控制器(MCU)市场:各ASIL等级

  • ASIL D
    • 双核心锁步 ASIL D
    • 三核心锁步 ASIL D
    • 故障运行 ASIL D
  • ASIL C
  • ASIL B
  • ASIL A
  • 品质管理(非安全)

第八章 全球功能安全微控制器 (MCU) 市场(以核心架构划分)

  • 多核心锁步
    • 双核锁步
    • 有投票机制的三核锁步
    • 四核心双锁步对
  • 非对称多核
    • 锁步 + 独立核心
    • 异构多核心(R 核心 + A-Core)
    • 混合关键性架构
  • 有安全特性的单核
    • 全面的BIST和诊断功能
    • 记忆体保护和ECC
    • 週边监控
  • 三重模组冗余 (TMR)

第九章:全球功能安全微控制器 (MCU) 市场(依週边组件划分)

  • 整合安全週边设
    • 安全增强型CAN/CAN FD
    • 有安全特性的汽车以太网
    • 冗余ADC通道
    • 安全PWM产生器
    • ECC保护的内存
  • 外部安全配套晶片
    • 系统基础晶片 (SBC)
    • 安全电源管理IC
    • 安全监控 IC
  • 感测器介面週边
  • 通讯介面外设
  • 硬体安全模组 (HSM)

第十章 全球功能安全微控制器 (MCU) 市场(依软体支援划分)

  • AUTOSAR 合规性
    • AUTOSAR 经典平台
    • AUTOSAR 自适应平台
    • MCAL(微控制器抽象层)
    • 安全库和手册
  • 专有即时作业系统
    • 认证安全即时作业系统
    • 硬实时内核
  • 裸机/无作业系统
  • 虚拟机器管理程式和虚拟化支持
  • 安全认证支援与工具

第十一章 全球功能安全微控制器(MCU)依应用划分的市场

  • 自动驾驶与进阶驾驶辅助系统 (ADAS)
    • 感测器处理(摄影机、雷达、光达)
    • 感测器融合与环境建模
    • 路径规划与决策
    • 车辆动力学控制
    • 安全监控与备用系统
  • 底盘和安全系统
    • 电子稳定控制系统 (ESC)
    • 防锁死煞车系统 (ABS)
    • 电动动力系统电动辅助方向机系统 (EPS)
    • 线控煞车
    • 线控转向
  • 动力系统和电气化
    • 电池管理系统 (BMS)
    • 牵引逆变器控制
    • 车用充电器控制
    • 混合动力系统控制
    • 引擎管理系统
  • 车身及舒适系统
  • 闸道及通讯控制器
  • 网域控制器

第十二章 全球功能安全微控制器 (MCU) 市场(依车辆类型划分)

  • 搭乘车
    • 紧凑型与中型轿车
    • 豪华型和高阶轿车
    • SUV 与跨界车
  • 电动车 (EV)
    • 纯电动车 (BEV)
    • 插电式油电混合动力车 (PHEV)
  • 商用车
    • 轻型商用车
    • 重型卡车
    • 公车
  • 自动驾驶汽车

第十三章 功能安全微控制器(MCU)依地区划分的市场

  • 北美洲
    • 美国
    • 加拿大
  • 欧洲
    • 德国
    • 英国
    • 法国
    • 义大利
    • 西班牙
    • 欧洲其他地区
  • 亚太地区
    • 中国
    • 日本
    • 韩国
    • 印度
    • 台湾
    • 东南亚
    • 亚太其他地区
  • 拉丁美洲
    • 巴西
    • 墨西哥
    • 阿根廷
    • 拉丁美洲其他地区
  • 中东和非洲
    • 沙乌地阿拉伯
    • 阿拉伯联合大公国
    • 中东其他地区非洲

第14章 企业简介

  • Infineon Technologies AG
  • NXP Semiconductors N.V.
  • Renesas Electronics Corporation
  • STMicroelectronics N.V.
  • Texas Instruments Incorporated
  • Microchip Technology Inc.
  • Analog Devices Inc.
  • ON Semiconductor Corporation
  • ROHM Co. Ltd.
  • Toshiba Electronic Devices &Storage Corporation
  • Fujitsu Limited
  • Hitachi Automotive Systems Ltd.
  • Kalray SA
  • Nordic Semiconductor ASA
  • Telechips Inc.
  • SiEngine Technology
  • Horizon Robotics
  • Black Sesame Technologies
  • Arm Holdings plc
  • Mobileye(Intel Corporation)
  • Others

第15章 附录

简介目录
Product Code: MRAUTO - 1041662

Functional Safety Microcontrollers (MCUs) Market by ASIL Level (A, B, C, D), Core Architecture (Single Core, Multi-Core), Peripherals (Safety Monitors, Watchdogs, EDAC), Software Support (AUTOSAR), Application (ADAS, Powertrain, Body Control), and Geography - Global Forecasts (2026-2036)

According to the research report titled, 'Functional Safety Microcontrollers (MCUs) Market by ASIL Level (A, B, C, D), Core Architecture (Single Core, Multi-Core), Peripherals (Safety Monitors, Watchdogs, EDAC), Software Support (AUTOSAR), Application (ADAS, Powertrain, Body Control), and Geography - Global Forecasts (2026-2036),' the functional safety microcontrollers market is projected to reach USD 14.73 billion by 2036, at a CAGR of 11.6% during the forecast period 2026-2036. The report provides an in-depth analysis of the global functional safety microcontrollers market across five major regions, emphasizing the current market trends, market sizes, recent developments, and forecasts till 2036. Following extensive secondary and primary research and an in-depth analysis of the market scenario, the report conducts the impact analysis of the key industry drivers, restraints, opportunities, and challenges. The growth of this market is driven by stringent automotive safety regulations (ISO 26262), strong presence of premium automotive manufacturers implementing advanced safety systems, established automotive safety culture requiring ISO 26262 compliance, rapidly growing automotive production, increasing adoption of ADAS and autonomous driving technologies, expanding electric vehicle segment requiring safety-certified control systems, and rising safety awareness in emerging automotive markets. Moreover, the integration of advanced hardware-level safety features, the development of redundant processing cores for lockstep operation, the adoption of built-in self-test (BiST) capabilities, the increasing focus on safety monitors and watchdogs, and the growing demand for fail-safe state management are expected to support the market's growth.

Key Players

The key players operating in the functional safety microcontrollers market are Infineon Technologies AG (Germany), NXP Semiconductors N.V. (Netherlands), STMicroelectronics N.V. (Switzerland), Renesas Electronics Corporation (Japan), Texas Instruments Inc. (U.S.), Microchip Technology Inc. (U.S.), Qualcomm Technologies Inc. (U.S.), Mobileye (Intel subsidiary) (Israel), Nvidia Corporation (U.S.), Xilinx Inc./AMD (U.S.), Altera/Intel (U.S.), Lattice Semiconductor Corporation (U.S.), Analog Devices Inc. (U.S.), Maxim Integrated/Analog Devices (U.S.), Cypress Semiconductor/Infineon (U.S.), ON Semiconductor Corporation (U.S.), Broadcom Inc. (U.S.), Qorvo Inc. (U.S.), Skyworks Solutions Inc. (U.S.), and Semtech Corporation (U.S.), among others.

Market Segmentation

The functional safety microcontrollers market is segmented by ASIL level (ASIL A, ASIL B, ASIL C, ASIL D), core architecture (single core, multi-core with lockstep), peripherals (safety monitors, watchdogs, error detection and correction (EDAC), and others), software support (AUTOSAR, non-AUTOSAR), application (ADAS, powertrain control, body control and infotainment, battery management systems, and others), and geography. The study also evaluates industry competitors and analyzes the market at the country level.

Based on ASIL Level

Based on ASIL level, the ASIL C and ASIL D segments hold the largest combined share of the market in 2026. This segment's dominance is primarily attributed to the critical nature of safety-critical automotive applications requiring the highest safety integrity levels. The ASIL B segment is expected to grow at a significant CAGR during the forecast period, driven by adoption in mid-range safety applications. The ASIL A segment maintains steady demand for less critical safety functions.

Based on Core Architecture

Based on core architecture, the multi-core with lockstep segment is estimated to hold the largest share of the market in 2026. This segment's dominance is primarily attributed to its superior redundancy and fault-tolerance capabilities for safety-critical applications. The single core segment is expected to maintain a significant share, driven by cost-effectiveness for lower ASIL level applications.

Based on Peripherals

Based on peripherals, the safety monitors and watchdogs segment is expected to account for substantial share of the market. This segment's dominance is driven by their critical importance in detecting and responding to potential failures. The EDAC (error detection and correction) segment is expected to grow at the highest CAGR during the forecast period, driven by increasing adoption in memory protection and data integrity applications.

Based on Application

Based on application, the ADAS segment is expected to witness significant growth during the forecast period. This segment's growth is fueled by rapid deployment of advanced driver assistance systems and autonomous driving technologies. The powertrain control segment holds a substantial share, driven by critical safety requirements in engine and transmission management. The body control and infotainment segment is expected to grow at a significant CAGR, driven by increasing integration of safety functions in vehicle body systems.

Geographic Analysis

An in-depth geographic analysis of the industry provides detailed qualitative and quantitative insights into the five major regions (North America, Europe, Asia-Pacific, Latin America, and the Middle East & Africa) and the coverage of major countries in each region. In 2026, Europe is estimated to account for the largest share of the global functional safety microcontrollers market, driven by stringent automotive safety regulations, strong presence of premium automotive manufacturers implementing advanced safety systems, and established automotive safety culture requiring ISO 26262 compliance. Asia-Pacific is projected to register the highest CAGR during the forecast period, fueled by rapidly growing automotive production, increasing adoption of ADAS and autonomous driving technologies, expanding electric vehicle segment requiring safety-certified control systems, and rising safety awareness in emerging automotive markets. The region's rapid market transformation is creating substantial opportunities.

Key Questions Answered in the Report-

  • What is the current revenue generated by the functional safety microcontrollers market globally?
  • At what rate is the global functional safety microcontrollers demand projected to grow for the next 7-10 years?
  • What are the historical market sizes and growth rates of the global functional safety microcontrollers market?
  • What are the major factors impacting the growth of this market at the regional and country levels? What are the major opportunities for existing players and new entrants in the market?
  • Which segments in terms of ASIL level, core architecture, peripherals, and application are expected to create major traction for the manufacturers in this market?
  • What are the key geographical trends in this market? Which regions/countries are expected to offer significant growth opportunities for the companies operating in the global functional safety microcontrollers market?
  • Who are the major players in the global functional safety microcontrollers market? What are their specific product offerings in this market?
  • What are the recent strategic developments in the global functional safety microcontrollers market? What are the impacts of these strategic developments on the market?

Scope of the Report:

Functional Safety Microcontrollers (MCUs) Market Assessment -- by ASIL Level

  • ASIL A
  • ASIL B
  • ASIL C
  • ASIL D

Functional Safety Microcontrollers (MCUs) Market Assessment -- by Core Architecture

  • Single Core
  • Multi-Core with Lockstep

Functional Safety Microcontrollers (MCUs) Market Assessment -- by Peripherals

  • Safety Monitors
  • Watchdogs
  • Error Detection and Correction (EDAC)
  • Other Peripherals

Functional Safety Microcontrollers (MCUs) Market Assessment -- by Software Support

  • AUTOSAR
  • Non-AUTOSAR

Functional Safety Microcontrollers (MCUs) Market Assessment -- by Application

  • ADAS (Advanced Driver Assistance Systems)
  • Powertrain Control
  • Body Control and Infotainment
  • Battery Management Systems
  • Other Applications

Functional Safety Microcontrollers (MCUs) Market Assessment -- by Geography

  • North America
  • U.S.
  • Canada
  • Europe
  • Germany
  • U.K.
  • France
  • Spain
  • Italy
  • Rest of Europe
  • Asia-Pacific
  • China
  • India
  • Japan
  • South Korea
  • Australia & New Zealand
  • Rest of Asia-Pacific
  • Latin America
  • Mexico
  • Brazil
  • Argentina
  • Rest of Latin America
  • Middle East & Africa
  • Saudi Arabia
  • UAE
  • South Africa
  • Rest of Middle East & Africa

TABLE OF CONTENTS

1. Introduction

  • 1.1. Market Definition
  • 1.2. Market Ecosystem
  • 1.3. Currency and Limitations
    • 1.3.1. Currency
    • 1.3.2. Limitations
  • 1.4. Key Stakeholders

2. Research Methodology

  • 2.1. Research Approach
  • 2.2. Data Collection & Validation
    • 2.2.1. Secondary Research
    • 2.2.2. Primary Research
  • 2.3. Market Assessment
    • 2.3.1. Market Size Estimation
    • 2.3.2. Bottom-Up Approach
    • 2.3.3. Top-Down Approach
    • 2.3.4. Growth Forecast
  • 2.4. Assumptions for the Study

3. Executive Summary

  • 3.1. Overview
  • 3.2. Market Analysis, by ASIL Level
  • 3.3. Market Analysis, by Core Architecture
  • 3.4. Market Analysis, by Peripherals
  • 3.5. Market Analysis, by Software Support
  • 3.6. Market Analysis, by Application
  • 3.7. Market Analysis, by Geography
  • 3.8. Competitive Analysis

4. Market Insights

  • 4.1. Introduction
  • 4.2. Global Functional Safety Microcontrollers (MCUs) Market: Impact Analysis of Market Drivers (2026-2036)
    • 4.2.1. Autonomous Driving and Advanced ADAS Deployment
    • 4.2.2. Electric Vehicle Electrification and X-by-Wire Systems
    • 4.2.3. Stringent Automotive Safety Standards and ISO 26262 Compliance
  • 4.3. Global Functional Safety Microcontrollers (MCUs) Market: Impact Analysis of Market Restraints (2026-2036)
    • 4.3.1. High Development and Certification Costs
    • 4.3.2. Long Qualification and Design-In Cycles
  • 4.4. Global Functional Safety Microcontrollers (MCUs) Market: Impact Analysis of Market Opportunities (2026-2036)
    • 4.4.1. Integration of AI Acceleration with Functional Safety
    • 4.4.2. Consolidation Through Domain and Zone Controllers
  • 4.5. Global Functional Safety Microcontrollers (MCUs) Market: Impact Analysis of Market Challenges (2026-2036)
    • 4.5.1. Balancing Performance Requirements with Safety Certification
    • 4.5.2. Managing Complexity of Mixed-Criticality Systems
  • 4.6. Global Functional Safety Microcontrollers (MCUs) Market: Impact Analysis of Market Trends (2026-2036)
    • 4.6.1. Evolution Toward Heterogeneous Safety Architectures
    • 4.6.2. Integration of Cybersecurity with Functional Safety
  • 4.7. Porter's Five Forces Analysis
    • 4.7.1. Threat of New Entrants
    • 4.7.2. Bargaining Power of Suppliers
    • 4.7.3. Bargaining Power of Buyers
    • 4.7.4. Threat of Substitute Products
    • 4.7.5. Competitive Rivalry

5. ISO 26262 and Automotive Functional Safety Standards

  • 5.1. Introduction to ISO 26262 Standard
  • 5.2. ASIL Classification and Requirements
  • 5.3. Safety Lifecycle and Development Process
  • 5.4. Hardware Safety Requirements and Metrics
  • 5.5. Software Safety Requirements
  • 5.6. Safety Case and Certification Process
  • 5.7. Emerging Standards for Autonomous Vehicles
  • 5.8. Regional Regulatory Variations
  • 5.9. Impact on Market Growth and Technology Adoption

6. Competitive Landscape

  • 6.1. Introduction
  • 6.2. Key Growth Strategies
    • 6.2.1. Market Differentiators
    • 6.2.2. Synergy Analysis: Major Deals & Strategic Alliances
  • 6.3. Competitive Dashboard
    • 6.3.1. Industry Leaders
    • 6.3.2. Market Differentiators
    • 6.3.3. Vanguards
    • 6.3.4. Emerging Companies
  • 6.4. Vendor Market Positioning
  • 6.5. Market Share/Ranking by Key Players

7. Global Functional Safety Microcontrollers (MCUs) Market, by ASIL Level

  • 7.1. Introduction
  • 7.2. ASIL D
    • 7.2.1. Dual-Core Lockstep ASIL D
    • 7.2.2. Triple-Core Lockstep ASIL D
    • 7.2.3. Fail-Operational ASIL D
  • 7.3. ASIL C
  • 7.4. ASIL B
  • 7.5. ASIL A
  • 7.6. QM (Quality Management - Non-Safety)

8. Global Functional Safety Microcontrollers (MCUs) Market, by Core Architecture

  • 8.1. Introduction
  • 8.2. Multi-Core Lockstep
    • 8.2.1. Dual-Core Lockstep
    • 8.2.2. Triple-Core Lockstep with Voting
    • 8.2.3. Quad-Core Dual Lockstep Pairs
  • 8.3. Multi-Core Asymmetric
    • 8.3.1. Lockstep + Independent Cores
    • 8.3.2. Heterogeneous Multi-Core (R+A cores)
    • 8.3.3. Mixed-Criticality Architectures
  • 8.4. Single-Core with Safety Mechanisms
    • 8.4.1. Comprehensive BIST and Diagnostics
    • 8.4.2. Memory Protection and ECC
    • 8.4.3. Peripheral Monitoring
  • 8.5. Triple Modular Redundancy (TMR)

9. Global Functional Safety Microcontrollers (MCUs) Market, by Peripherals

  • 9.1. Introduction
  • 9.2. Integrated Safety Peripherals
    • 9.2.1. Safety-Enhanced CAN/CAN FD
    • 9.2.2. Automotive Ethernet with Safety
    • 9.2.3. Redundant ADC Channels
    • 9.2.4. Safety PWM Generators
    • 9.2.5. Memory with ECC Protection
  • 9.3. External Safety Companion Chips
    • 9.3.1. System Basis Chips (SBC)
    • 9.3.2. Power Management ICs with Safety
    • 9.3.3. Safety Watchdog ICs
  • 9.4. Sensor Interface Peripherals
  • 9.5. Communication Interface Peripherals
  • 9.6. Hardware Security Modules (HSM)

10. Global Functional Safety Microcontrollers (MCUs) Market, by Software Support

  • 10.1. Introduction
  • 10.2. AUTOSAR-Compliant
    • 10.2.1. AUTOSAR Classic Platform
    • 10.2.2. AUTOSAR Adaptive Platform
    • 10.2.3. MCAL (Microcontroller Abstraction Layer)
    • 10.2.4. Safety Library and Manual
  • 10.3. Proprietary RTOS
    • 10.3.1. Certified Safety RTOS
    • 10.3.2. Hard Real-Time Kernels
  • 10.4. Bare-Metal / No OS
  • 10.5. Hypervisor and Virtualization Support
  • 10.6. Safety Certification Support and Tools

11. Global Functional Safety Microcontrollers (MCUs) Market, by Application

  • 11.1. Introduction
  • 11.2. Autonomous Driving and ADAS
    • 11.2.1. Sensor Processing (Camera, Radar, Lidar)
    • 11.2.2. Sensor Fusion and Environment Modeling
    • 11.2.3. Path Planning and Decision Making
    • 11.2.4. Vehicle Motion Control
    • 11.2.5. Safety Monitoring and Backup Systems
  • 11.3. Chassis and Safety Systems
    • 11.3.1. Electronic Stability Control (ESC)
    • 11.3.2. Anti-Lock Braking System (ABS)
    • 11.3.3. Electric Power Steering (EPS)
    • 11.3.4. Brake-by-Wire
    • 11.3.5. Steer-by-Wire
  • 11.4. Powertrain and Electrification
    • 11.4.1. Battery Management Systems (BMS)
    • 11.4.2. Traction Inverter Control
    • 11.4.3. On-Board Charger Control
    • 11.4.4. Hybrid Powertrain Control
    • 11.4.5. Engine Management Systems
  • 11.5. Body and Comfort Systems
  • 11.6. Gateway and Communication Controllers
  • 11.7. Domain Controllers

12. Global Functional Safety Microcontrollers (MCUs) Market, by Vehicle Type

  • 12.1. Introduction
  • 12.2. Passenger Vehicles
    • 12.2.1. Compact and Mid-Size Vehicles
    • 12.2.2. Luxury and Premium Vehicles
    • 12.2.3. SUVs and Crossovers
  • 12.3. Electric Vehicles (EVs)
    • 12.3.1. Battery Electric Vehicles (BEVs)
    • 12.3.2. Plug-in Hybrid Electric Vehicles (PHEVs)
  • 12.4. Commercial Vehicles
    • 12.4.1. Light Commercial Vehicles
    • 12.4.2. Heavy-Duty Trucks
    • 12.4.3. Buses
  • 12.5. Autonomous Vehicles

13. Functional Safety Microcontrollers (MCUs) Market, by Geography

  • 13.1. Introduction
  • 13.2. North America
    • 13.2.1. U.S.
    • 13.2.2. Canada
  • 13.3. Europe
    • 13.3.1. Germany
    • 13.3.2. U.K.
    • 13.3.3. France
    • 13.3.4. Italy
    • 13.3.5. Spain
    • 13.3.6. Rest of Europe
  • 13.4. Asia-Pacific
    • 13.4.1. China
    • 13.4.2. Japan
    • 13.4.3. South Korea
    • 13.4.4. India
    • 13.4.5. Taiwan
    • 13.4.6. Southeast Asia
    • 13.4.7. Rest of Asia-Pacific
  • 13.5. Latin America
    • 13.5.1. Brazil
    • 13.5.2. Mexico
    • 13.5.3. Argentina
    • 13.5.4. Rest of Latin America
  • 13.6. Middle East & Africa
    • 13.6.1. Saudi Arabia
    • 13.6.2. UAE
    • 13.6.3. Rest of Middle East & Africa

14. Company Profiles

  • 14.1. Infineon Technologies AG
  • 14.2. NXP Semiconductors N.V.
  • 14.3. Renesas Electronics Corporation
  • 14.4. STMicroelectronics N.V.
  • 14.5. Texas Instruments Incorporated
  • 14.6. Microchip Technology Inc.
  • 14.7. Analog Devices Inc.
  • 14.8. ON Semiconductor Corporation
  • 14.9. ROHM Co. Ltd.
  • 14.10. Toshiba Electronic Devices & Storage Corporation
  • 14.11. Fujitsu Limited
  • 14.12. Hitachi Automotive Systems Ltd.
  • 14.13. Kalray SA
  • 14.14. Nordic Semiconductor ASA
  • 14.15. Telechips Inc.
  • 14.16. SiEngine Technology
  • 14.17. Horizon Robotics
  • 14.18. Black Sesame Technologies
  • 14.19. Arm Holdings plc
  • 14.20. Mobileye (Intel Corporation)
  • 14.21. Others

15. Appendix

  • 15.1. Questionnaire
  • 15.2. Available Customization