汽车用MEMS感测器（2025年）

汽车MEMS调查：单辆车上有超过100个MEMS感测器，产品创新国产化步伐极快。

MEMS（微机电系统）是将微机械结构、微感测器、微执行器、讯号处理与控制电路、通讯介面、电源模组等依功能需求整合在一个晶片上的一个微小元件或系统。 MEMS主要可分为MEMS感测器和MEMS执行器。

MEMS感测器由MEMS晶片和ASIC封装组成。 MEMS晶片将外界的物理、化学、生物等讯号转换成电讯号。 ASIC透过读取、处理和输出电讯号来获取外部资讯。与传统感测器相比，MEMS感测器可以把所有配件整合到一块很小的MEMS晶片上，具有整合度高、小型化、智慧化、重量轻、功耗低、功能多样等特点。

在汽车领域，MEMS感测器广泛应用于汽车ADAS、智慧座舱、车身舒适系统、动力总成和底盘系统。高精度定位、健康驾驶舱（空气品质）、车载心率监测、智慧车钥匙、主动降噪、热泵空调、安全气囊、引擎、电池管理系统（BMS）、电子稳定程序、防锁死煞车系统（ ABS），广泛应用于电子悬吊控制、轮胎压力监测系统（TPMS）等。

在汽车应用的MEMS产品中，压力感测器、惯性感测器和麦克风应用最为广泛，占汽车MEMS的99%。未来随着汽车智慧化、系统整合化以及MEMS相关装置研发的不断深入，在汽车上应用的MEMS感测器种类将会更加丰富。

MEMS 惯性感测器：更多 MEMS IMU 将用于自动驾驶

MEMS惯性感测器是新能源汽车智慧驾驶感知的基础。 MEMS惯性感测器主要包括MEMS陀螺仪、MEMS加速度计、MEMS IMU。这些可用于测量移动车辆的加速度和角速度，并提供即时车辆运动姿态和轨迹。 MEMS惯性感测器（加速度计、陀螺仪）最早应用于安全气囊和电子稳定控制系统。随着自动驾驶的发展，MEMS IMU在高精度定位导航场景的应用不断拓展。

MEMS IMU 整合了 MEMS 加速度计、MEMS 陀螺仪和运动/姿态演算法。在经典的智慧驾驶场景中，MEMS IMU常用于车辆定位导航、动作辨识、环境感知辅助、控制、决策支援等模组和功能。

在端到端的智慧驾驶解决方案中，将IMU整合到网域控制器中正在成为主流。随着自动驾驶的推进，要求车辆在感知和定位方面实现更高的精度和安全性。车辆位置资讯需要高度准确和可靠。特别是L3/L3+自动驾驶汽车，需要更高精度的定位。预计对 MEMS IMU 的要求会越来越高。

高精度、高稳定性：高精度IMU提供更精准的车辆姿态讯息，帮助系统更瞭解车辆在空间中的位置和方向。此外，IMU的稳定性对于系统的可靠性至关重要。 IMU在长期运作过程中必须保持稳定的性能并输出可靠的数据，而不受温度变化、振动等环境因素的影响。

本报告对中国汽车产业进行了调查分析，提供了MEMS感测器在汽车上的应用场景，并提供了国内外供应商的资讯。

目录

第 1 章 汽车 MEMS 产业概论

• MEMS 感测器概述
• 汽车 MEMS 感知器标准
• MEMS市场
• 汽车 MEMS 市场
• MEMS感测器产业链

第 2 章 汽车 MEMS 感知器应用场景 - 自动驾驶/ADAS

• MEMS感测器在智慧驾驶的应用
• 智慧驾驶场景下的MEMS感测器应用方案、产品总结

第3章 汽车MEMS感测器应用场景-座舱娱乐

• MEMS感测器在智慧驾驶舱的应用
• 智慧座舱场景下的MEMS感测器应用方案、产品总结

第 4 章 汽车 MEMS 感知器应用场景 – 车身电子

• MEMS感测器在车身电子系统的应用
• 车身电子 MEMS 感测器应用解决方案，产品摘要

第5章 MEMS 感测器在汽车-动力总成中的应用场景

• MEMS感测器在动力传动系统的应用
• MEMS感测器在动力传动系统中的应用解决方案，产品概要

第6章 汽车MEMS感测器应用场景-底盘

• MEMS感测器在底盘的应用
• 底盘 MEMS 感测器应用解决方案，产品摘要

第7章 国外汽车MEMS感知器供应商

• 博世 意法半导体
• 阿迪尔
• 英飞凌 恩智浦
• 迈来芯
• TDK
• 村田
• 森萨塔 松下

第 8 章：中国汽车 MEMS 感知器供应商

• Anhui XDLK Microsystem
• NOVOSENSE
• Ampron
• QST
• MiraMEMS
• AAC Technologies
• MEMSIC
• MT Microsystems
• MEMSensing
• Asensing Technology
• Huaxin Semiconductor
• Rsentech
• Winsen
• ASAIR
• NationalChip

Automotive MEMS Research: A single vehicle packs 100+ MEMS sensors, and the pace of product innovation and localization are becoming much faster.

MEMS (Micro Electromechanical System) is a micro device or system that integrates micromechanical structures, micro sensors, micro actuators, signal processing and control circuits, communication interfaces and power modules on a chip according to functional requirements. MEMSs are mainly divided into MEMS sensors and MEMS actuators.

MEMS sensor is composed of MEMS chip and ASIC packaging. The MEMS chip converts external physical, chemical, biological and other signals into electrical signals. The ASIC reads the electrical signals, and processes and outputs them, thereby acquiring external information. Compared with traditional sensors, the MEMS sensor can integrate all accessories on a very small MEMS chip, and features high integration, miniaturization, intelligence, low weight, low power consumption and multiple functions.

In the automotive field, MEMS sensors are widely used in automotive ADAS, intelligent cockpits, body comfort systems, powertrains and chassis systems. They find application in high-precision positioning, healthy cockpit (air quality), in-car heartbeat monitoring, smart car key, active noise reduction, heat pump air conditioner, airbag, engine, battery management system (BMS), electronic stability program, and anti-lock braking system (ABS), electronically controlled suspension and tire pressure monitoring system (TPMS).

Among MEMS products for automotive applications, pressure sensors, inertial sensors and microphones employ the most MEMS sensors, sweeping 99% of automotive MEMS. In the future, with vehicle intelligence, system integration and the R&D of MEMS-related devices, more diversified MEMS sensors will be applied to vehicles.

MEMS inertial sensors: more MEMS IMUs will be applied in autonomous driving

MEMS inertial sensors are the basis for intelligent driving perception of new energy vehicles. They mainly include MEMS gyroscope, MEMS accelerometer, and MEMS IMU. They can be used to measure the acceleration and angular velocity of vehicles while driving, and provide real-time vehicle motion posture and trajectory. MEMS inertial sensors (accelerometer, gyroscope) were first used in airbags and electronic stability control systems. As autonomous driving develops, the application of MEMS IMUs in high-precision positioning and navigation scenarios has been expanded.

MEMS IMU integrates MEMS accelerometer, MEMS gyroscope, and motion/attitude algorithm. In classic intelligent driving scenarios, MEMS IMU is often used in modules and functions such as vehicle positioning and navigation, motion perception, environmental perception assistance, control and decision-making support.

In end-to-end intelligent driving solutions, the solution of integrating IMUs into domain controllers has become the mainstream option. With the evolution of autonomous driving, vehicles have higher accuracy and safety requirements for perception and positioning. It is necessary to ensure that vehicle position information is highly accurate and reliable. In particular, L3/L3+ autonomous vehicles need to have higher-precision positioning. The requirements for MEMS IMUs will become ever higher:

High accuracy and stability: High-precision IMUs can provide more accurate vehicle attitude information to help systems better understand the position and direction of vehicles in space. Also the stability of IMUs is crucial to the reliability of systems. During long-term operation, IMUs need to maintain stable performance and output reliable data, without being affected by environmental factors such as temperature changes and vibration.

Quick response and high update frequency: End-to-end intelligent driving systems need to make a quick response to environmental changes, so IMUs need to respond quickly and update data frequently.

Compatibility with deep learning models: End-to-end intelligent driving systems generally use deep learning models to process sensor data, so IMUs need to provide data formats that are compatible with deep learning models.

High reliability and fault analysis: End-to-end intelligent driving systems pose extremely high safety requirements, including normal operation in various harsh environments such as high temperature, low temperature, high humidity and intense vibration, so IMUs need to offer high reliability. Moreover due to the complexity of end-to-end systems, IMUs need to have the ability to detect and diagnose faults. When IMU fails, the intelligent driving system can detect the failure in time and take corresponding measures, for example, switching to backup sensors or decelerating, so as to ensure the safety of the vehicle.

In November 2024, Murata Manufacturing Co., Ltd. unveiled its latest innovation in automotive sensor technology, the SCH1633-D01. The 6-axis MEMS inertial sensor is designed to meet the increasing demand for precision in autonomous driving (AD), advanced driver-assistance systems (ADAS), and other key automotive functions, including inertial navigation, vehicle stability control, and headlight alignment. It is the smallest product among Murata's automotive-grade IMUs.

The automotive 6-axis MEMS IMU integrates a 3-axis accelerometer and a 3-axis gyroscope, with the acceleration range of +-8g, the angular velocity range of +-62.5dps~+-300dps, and built-in orthogonal error compensation. It enables extremely smooth and high-resolution output. The IMU features time synchronization, providing the signals required for GNSS dead reckoning, vehicle attitude measurement, camera/LiDAR/radar tilt detection, to handle the time misalignment between these signals.

In the field of automotive MEMS IMU, most high-precision MEMS IMUs are imported. As China's new energy vehicle industry gains an edge and opportunities, automotive MEMS IMUs made in China are accelerating the pace of replacing imports. Chinese companies such as QST, Asensing Technology, MT Microsystems, AAC Technologies, Huaxin Semiconductor, DAISCH and Aceinna are deploying automotive MEMS IMUs.

In July 2024, QST released new six-axis MEMS IMUs, QMI8A01 and QMI8A01z. QMI8A01z has been certified by AEC-Q100 Grade 2.

The board-level sensitivity error of the MEMS gyroscope in QMI8A01z reaches +-1%, and the TCS of the MEMS accelerometer is 0.0025%/°C. In harsh application scenarios, QMI8A01z can minimize the impact of the environment and help technicians develop more flexible algorithms. In addition, it supports SPI, I2C, and I3C communication protocols. To make it easier for application developers to develop, the sensor has a built-in intelligent algorithm which mainly integrates AnyMotion, No-Motion, and SignificantMotion to detect motion/stationary/continuous movement and output the corresponding interrupt signal.

MEMS pressure sensors: MEMS pressure sensors will be used more widely in thermal runaway monitoring.

MEMS pressure sensors are largely seen in the power domain, chassis domain and cockpit domain of vehicles. In traditional ICE vehicles, MEMS pressure sensors find broad application in pressure detection of gearboxes and engines. In the field of new energy vehicles, the rapid development of electric vehicles may mean that the demand for pressure sensors in the power systems of traditional ICE vehicles will slow down. Meanwhile, some new application scenarios for MEMS pressure sensors will also appear. For example, there are seat pressure sensors and heat pump air conditioning pressure and temperature composite sensors in the cockpit domain, and battery pack pressure sensors in the power domain. MEMS pressure sensors are expected to be used much more widely in thermal runaway monitoring in BMS.

At present, the power batteries for new energy vehicles are led by lithium batteries. Overcharge, over-discharge, overheating, short circuit, high temperature, extrusion, collision, water intrusion and so on may cause thermal runaway of battery packs. In the case of thermal runaway, multiple chemical reactions will occur inside battery packs, generating heat and gas and increasing internal pressure of the batteries. At this time, the pressure change in the battery pack can be detected by pressure sensors.

NXP NBP8 and NBP9 is a fully integrated battery pressure monitor sensor family. This solution has a built-in MCU and battery pressure monitor sensors (BPMS), and integrates an 8-bit central processing unit (CPU) and firmware provided by NXP. NBP8xx can detect pressure and wake up the main MCU when a change in pressure is detected. The pressure sensors located in the battery monitoring unit communicate with the main MCU which then notifies the driver to escape from the vehicle quickly before thermal runaway occurs.

MEMS microphones: Intelligent driving perception will boost automotive MEMS silicon microphones.

Automotive MEMS microphones can be used for in-vehicle and out-of-vehicle sound pickup. In-vehicle sound pickup applications mainly include hands-free calls, voice interaction, and active noise reduction. Out-of-vehicle sound pickup applications contain environmental perception and external voice pickup for road condition detection and (ambulance/police car) sirens detection.

ADAS generally collects data based on the position of cameras, radars or LiDAR and can only detect and recognize objects within its field of view. L3/L4 autonomous driving systems, there will be higher requirements for the detection of approaching emergency vehicles. L3/L4 autonomous driving requires vehicles to detect and respond to dynamic driving environments, such as ambulances, police cars and other emergency service vehicles. If the line of sight is blocked, vision-based perception is obviously unable to detect the approach of emergency vehicles in time.

Automotive MEMS microphones can provide vehicles with hearing capabilities, and perceive the approach of emergency vehicles in advance before visual sensors. Microphones with extremely high sensitivity can detect surrounding sounds without being heard by human ears, and warn of approaching objects in advance, leaving drivers or autonomous driving systems more time to respond, and improving the safety of the systems.

Infineon and Reality AI have jointly created an advanced sensing solution giving vehicles the sense of hearing. This solution adds XENSIV(TM) MEMS microphones to existing sensor systems. It enables cars to "see" around the corner and to warn about moving objects hidden in the blind spot or approaching emergency vehicles that are still too distant to see.

The new sensing solution is based on Infineon XENSIV(TM) MEMS microphones (IM67D130A) in combination with AURIX(TM) microcontrollers (MCU) and Reality AI's Automotive See-With-Sound (SWS) system. Infineon IM67D130A has a low THD and an acoustic overload point (AOP) of 130dB SPL, which allows the automotive MEMS silicon microphone to capture distortion-free audio signals in noisy environments, thereby eliminating noise hidden in high background noise or wind noise and reliably recognizing alarm sounds in the system.

Using machine learning-based algorithms, the system is able to detect emergency vehicles, cars and other road participants - even if they cannot be seen by drivers or detected by the sensors incorporated in the vehicles' ADAS. Machine learning also ensures that the country-specific sirens of emergency vehicles are recognized in all parts of the world.

For processing the audio signal, the Reality AI software makes use of Infineon's AURIX TC3x family of MCUs which is widely used across multiple automotive applications. The scalable MCU family offers a range from one to six cores and up to 16 MB of Flash with functional safety up to ASIL-D according to the ISO26262 2018 standard and EVITA full cybersecurity.

Table of Contents

1 Overview of Automotive MEMS Industry

• 1.1 Overview of MEMS Sensors
• Classification of Automotive Sensors (by Information Collected)
• Structure and Features of MEMS
• Working Principle and Classification of MEMS
• Application of MEMS Sensors in Automotive Electronics
• Classification and Application of Automotive MEMS Sensors
• MEMS Inertial Sensors: Classification and Application
• MEMS Inertial Sensors: Accelerometer Architecture and Automotive Application
• MEMS Inertial Sensors: Gyroscope Architecture and Automotive Application
• MEMS Inertial Sensors: MEMS IMU Application Scenarios
• MEMS Inertial Sensors: Key Technical Parameters
• MEMS Inertial Sensors: Key Performance - Bias Instability
• MEMS Pressure Sensors: Classification and Working Principle
• MEMS Pressure Sensors: Automotive Application Classification (1)
• MEMS Pressure Sensors: Automotive Application Classification (2)
• MEMS Pressure Sensors: Automotive Application Classification (3)
• MEMS Pressure Sensors: Application Comparison between Fuel Vehicles and Battery-electric Vehicles
• MEMS Microphones: Structure and Working Principle
• MEMS Microphones: Key Performance Indicators
• MEMS Microphones: Automotive Application Scope
• MEMS Microphones: Typical Automotive Scenarios - In-vehicle Sound Pickup
• MEMS Microphones: Typical Automotive Scenarios - Out-of-vehicle Sound Pickup
• MEMS Flow Sensors: Working Principle and Automotive Application
• MEMS Temperature Sensors: Working Principle and Automotive Application
• MEMS Temperature and Humidity Sensor: Automotive Applications
• 1.2 Automotive MEMS Sensor Standards
• Automotive MEMS Sensor Certification Standard: AEC-Q103
• Automotive MEMS Standardization Process in China
• 1.3 MEMS Market
• Global MEMS Market Size, 2023-2029E (by Downstream Application)
• Global MEMS Market Growth Rate, 2023-2029E (by Downstream Application)
• Competitive Landscape of Global MEMS Sensor Industry
• Competitive Landscape of China's MEMS Sensor Industry
• 1.4 Automotive MEMS Market
• Barriers to Automotive MEMS Industry
• Incremental Momentum for Automotive MEMS Market
• Global Automotive MEMS Market Share (by Product Category)
• MEMS Demand and Market Size in China's Passenger Car Market, 2023~2029E
• Automotive MEMS Inertial Sensor Market: China's Automotive MEMS Inertial Sensor Market Landscape
• Automotive MEMS Inertial Sensor Market: Automotive MEMS Accelerometer Price
• Automotive MEMS Inertial Sensor Market: Automotive MEMS Gyroscope Price
• Automotive MEMS Inertial Sensor Market: Automotive MEMS IMU Price
• Automotive MEMS Inertial Sensor Market: Autonomous Driving Penetration Rate in China's Passenger Car Market, 2023~2028E
• Automotive MEMS Inertial Sensor Market: China's Passenger Car MEMS Inertial Sensor Market Size, 2023~2028E (1)
• Automotive MEMS Inertial Sensor Market: China's Passenger Car MEMS Inertial Sensor Market Size, 2023~2028E (2)
• Automotive MEMS Pressure Sensor Market: China's Automotive MEMS Pressure Sensor Market Landscape
• Automotive MEMS Pressure Sensor Market: Growth Trend in the Automotive Field
• Automotive MEMS Pressure Sensor Market: Long-term Trend of MEMS Pressure Sensors in Power Systems
• Automotive MEMS Pressure Sensor Market: Automotive MEMS Pressure Sensor Price
• Automotive MEMS Pressure Sensor Market: China's Passenger Car MEMS Pressure Sensor Market Size, 2023~2028E
• Automotive MEMS Microphone Market: China's Automotive MEMS Microphone Market Landscape
• Automotive MEMS Microphone Market: Automotive MEMS Silicon Microphone Price
• Automotive MEMS Microphone Market: China's Passenger Car MEMS Microphone Market, 2023~2028E
• 1.5 MEMS Sensor Industry Chain
• MEMS Sensor Industry Chain
• Market Landscape of MEMS Sensor Industry Chain
• Status Quo of China's MEMS Industry (1)
• Status Quo of China's MEMS Industry (2)
• MEMS Manufacturing: General Manufacturing Process of MEMS
• MEMS Manufacturing: Three Processing Types of MEMS Substrates
• MEMS Manufacturing Model: IDM and Fabless
• Three Types of MEMS OEMs
• Summary of MEMS OEMs and Production Lines in China (1)
• Summary of MEMS OEMs and Production Lines in China (2)
• Summary of MEMS OEMs and Production Lines in China (3)
• MEMS Packaging: Technology Classification

2 Application Scenarios of Automotive MEMS Sensors - Autonomous Driving/ADAS

• 2.1 Application of MEMS Sensors in Intelligent Driving
• Application of MEMS Sensors in Intelligent Driving Systems
• Three Positioning Solutions for ADAS/Autonomous Driving Systems
• Features, Advantages and Disadvantages of MEMS IMUs in High-precision Positioning
• MEMS IMUs Become Key Sensors in Intelligent Driving
• Application of MEMS IMUs in Intelligent Driving Solutions
• Application of MEMS IMUs in Intelligent Driving (1): INS
• Application of MEMS IMU in Intelligent Driving (2):
• Application of MEMS IMU in Intelligent Driving (3)
• Application of MEMS IMU in Intelligent Driving (4)
• Three Integration Methods of "GNSS+IMU" Navigation (1): Loose Coupling
• Three Integration Methods of "GNSS+IMU" Navigation (2)
• Three Integration Methods of "GNSS+IMU" Navigation (3)
• Three Integration Methods of "GNSS+IMU" Navigation (4)
• Advanced Requirements for IMUs in End-to-end Intelligent Driving Solutions
• Application and Difference of MEMS IMUs in End-to-end Intelligent Driving Solutions
• Innovative Application of MEMS in Intelligent Driving Systems: MEMS Fast-moving Image Sensors
• 2.2 Application Solutions of MEMS Sensors in Intelligent Driving Scenarios and Product Summary
• Summary of MEMS Accelerometers for Intelligent Driving (1)
• Summary of MEMS Accelerometers for Intelligent Driving (2)
• Summary of MEMS Gyroscopes for Intelligent Driving
• Summary of MEMS IMUs for Intelligent Driving (1)
• Summary of MEMS IMUs for Intelligent Driving (2)
• Summary of MEMS IMUs for Intelligent Driving (3)
• Summary of MEMS IMUs for Intelligent Driving (4)
• Summary of MEMS IMUs for Intelligent Driving (5)
• Summary of MEMS IMUs for Intelligent Driving (6)
• Summary of MEMS IMUs for Intelligent Driving (7)
• Summary of MEMS Microphones for Intelligent Driving
• Intelligent Driving MEMS IMUs (1)
• Intelligent Driving MEMS IMUs (2)
• Intelligent Driving MEMS IMUs (3)
• Intelligent Driving MEMS IMUs (4)
• Intelligent Driving MEMS IMUs (5)
• Intelligent Driving MEMS IMUs (6)
• Intelligent Driving MEMS IMUs (7)
• Intelligent Driving MEMS Gyroscopes
• MEMS Application Solutions for Intelligent Driving Scenarios (1)
• MEMS Application Solutions for Intelligent Driving Scenarios (2)
• MEMS Application Solutions for Intelligent Driving Scenarios (3)
• MEMS Application Solutions for Intelligent Driving Scenarios (4)
• MEMS Application Solutions for Intelligent Driving Scenarios (5)

3 Application Scenarios of Automotive MEMS Sensors - Cockpit Entertainment

• 3.1 Application of MEMS Sensors in Intelligent Cockpits
• Sensor Types in Intelligent Cockpits
• Typical Applications of MEMS Silicon Microphones in Intelligent Cockpits (1): Voice interaction & eCall
• Typical Applications of MEMS Silicon Microphones in Intelligent Cockpits (2): Automotive Noise Control
• RNC System Market
• Typical Applications of MEMS Inertial Sensors in Intelligent Cockpits: Road Noise Cancellation (RNC)
• Typical Applications of MEMS Ultrasonic Sensors in Intelligent Cockpits: Rear Occupant Alert (ROA)
• 3.2 Application Solutions of MEMS Sensors in Intelligent Cockpit Scenarios and Product Summary
• Summary of MEMS Accelerometers for Intelligent Cockpits (1)
• Summary of MEMS Accelerometers for Intelligent Cockpits (2)
• Summary of MEMS Gyroscopes for Intelligent Cockpits
• Summary of MEMS IMUs for Intelligent Cockpits (1)
• Summary of MEMS IMUs for Intelligent Cockpits (2)
• Summary of MEMS Microphones for Intelligent Cockpits (1)
• Summary of MEMS Microphones for Intelligent Cockpits (2)
• Summary of MEMS Microphones for Intelligent Cockpits (3)
• MEMS Accelerometers for Intelligent Cockpits (1)
• MEMS Accelerometers for Intelligent Cockpits (2)
• MEMS Silicon Microphones for Intelligent Cockpits (1)
• MEMS Silicon Microphones for Intelligent Cockpits (2)
• MEMS Application Solutions for Intelligent Cockpit Scenarios (1)
• MEMS Application Solutions for Intelligent Cockpit Scenarios (2)
• MEMS Application Solutions for Intelligent Cockpit Scenarios (3)

4 Application Scenarios of Automotive MEMS Sensors - Body Electronics

• 4.1 Application of MEMS Sensors in Body Electronics
• Main Sensors for Thermal Management Systems of New Energy Vehicles
• Distribution of Pressure Sensors and Temperature Sensors in Thermal Management Systems of New Energy Vehicles
• Technical Route of Pressure/Temperature and Pressure Integrated Sensors in Traditional Refrigerant Systems
• Sensor Solutions for Future Thermal Management Systems
• Typical Applications of MEMS Sensors in Body Electronics (1)
• Typical Applications of MEMS Sensors in Body Electronics (2)
• Typical Applications of MEMS Sensors in Body Electronics (3)
• Typical Applications of MEMS Sensors in Body Electronics (4)
• 4.2 Application Solutions of MEMS Sensors in Body Electronics and Product Summary
• Summary of MEMS Accelerometers for Body Electronics (1)
• Summary of MEMS Accelerometers for Body Electronics (2)
• Summary of MEMS Gyroscopes for body electronics
• Summary of MEMS IMUs for Body Electronics
• Summary of MEMS Pressure Sensors for Body Electronics
• MEMS Pressure Sensors for Body Electronics (1)
• MEMS Pressure Sensors for Body Electronics (2)
• MEMS Pressure Sensors for Body Electronics (3)
• MEMS Application Solutions for Body Electronics (1)
• MEMS Application Solutions for Body Electronics (2)
• MEMS Application Solutions for Body Electronics (3)
• MEMS Application Solutions for Body Electronics (4)

5 Application Scenarios of Automotive MEMS Sensors - Powertrain

• 5.1 Application of MEMS Sensors in Powertrains
• Application MEMS Sensors in Automotive Engines
• Application of MEMS Pressure Sensors in Power Domain
• Typical Applications of MEMS Pressure Sensors in Powertrains (1): Engine Management Systems of Traditional Fuel Vehicles
• Typical Applications of MEMS Pressure Sensors in Powertrains (2): Battery Pack Pressure Sensors for New Energy Vehicles
• Typical Applications of MEMS IMUs in Powertrains
• Main Sensors of New Energy Hydrogen Fuel Vehicles
• 5.2 Application Solutions of MEMS Sensors in Powertrains and Product Summary
• Summary of MEMS Pressure Sensors for Powertrains (1)
• Summary of MEMS Pressure Sensors for Powertrains (2)
• Summary of MEMS Pressure Sensors for Powertrains (3)
• Summary of MEMS Pressure Sensors for Powertrains (4)
• Summary of MEMS Pressure Sensors for Powertrains (5)
• Powertrain MEMS Pressure Sensors (1)
• Powertrain MEMS Pressure Sensors (2)
• MEMS Application Solutions for Powertrains (1)
• MEMS Application Solutions for Powertrains (2)
• MEMS Application Solutions for Powertrains (3)
• MEMS Application Solutions for Powertrains (4)

6 Application Scenarios of Automotive MEMS Sensors - Chassis

• 6.1 Application of MEMS Sensors in Chassis
• Sensors in Automotive Chassis Control Systems
• Application of MEMS Pressure Sensors in Chassis Domain
• Typical Applications of MEMS Sensors in Chassis (1): Suspension Systems
• Typical Applications of MEMS Sensors in Chassis (2)
• Typical Applications of MEMS Sensors in Chassis (3)
• Typical Applications of MEMS Sensors in Chassis (4)
• Development Trends of TMPS
• Requirements of Autonomous Driving Systems for Intelligent Tire Technology
• Requirements of Electrification for Intelligent Tire Technology
• 6.2 Application Solutions of MEMS Sensors in Chassis and Product Summary
• Summary of MEMS Accelerometers for Chassis (1)
• Summary of MEMS Accelerometers for Chassis (2)
• Summary of MEMS Gyroscopes for Chassis
• Summary of MEMS IMUs for Chassis (1)
• Summary of MEMS IMUs for Chassis (2)
• Summary of MEMS Pressure Sensors for Chassis (1)
• Summary of MEMS Pressure Sensors for Chassis (2)
• Summary of MEMS Pressure Sensors for Chassis (3)
• Summary of MEMS Gyroscopes for Chassis (1)
• Summary of MEMS Gyroscopes for Chassis (2)
• MEMS Application Solutions for Chassis (1)
• MEMS Application Solutions for Chassis (2)
• MEMS Application Solutions for Chassis (3)

7 Foreign Automotive MEMS Sensor Suppliers

• 7.1 Bosch
• Automotive MEMS Sensor Application Scenarios and Product Selection
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS Sensors (3)
• Automotive MEMS Sensors (4)
• Automotive MEMS IMU Application Solutions
• Automotive MEMS Acceleration Sensor Application Solutions (1)
• Automotive MEMS Acceleration Sensor Application Solutions (2)
• 7.2 STMicroelectronics
• Automotive MEMS Sensor Application Scenarios and Product Selection
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS IMU Application Solutions
• Automotive MEMS Acceleration Sensor Application Solutions
• 7.3 ADI
• MEMS Sensor Layout
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Sensors
• Automotive MEMS Sensor Application Solutions (1)
• Automotive MEMS Sensor Application Solutions (2)
• 7.4 Infineon
• MEMS Sensor Layout
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Overview of Automotive MEMS Pressure Sensors
• Automotive MEMS Pressure Sensors (1)
• Automotive MEMS Pressure Sensors (2)
• Automotive MEMS Pressure Sensor Application Solutions
• Automotive MEMS Microphone Application Scenarios
• Automotive MEMS Silicon Microphones
• Automotive MEMS Silicon Microphone Application Solutions
• Automotive MEMS Silicon Microphone Application Solutions
• 7.5 NXP
• Automotive MEMS Sensor Layout
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Pressure Sensors
• Automotive MEMS Pressure Sensor Application Solutions (1)
• Automotive MEMS Pressure Sensor Application Solutions (2)
• Automotive MEMS Pressure Sensor Application Solutions (3)
• Automotive MEMS Motion Sensor Application Solutions (4)
• 7.6 Melexis
• Automotive Electronic Product Line Layout
• Key Automotive MEMS Sensor Technologies (1)
• Key Automotive MEMS Sensor Technologies (2)
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Pressure Sensors (1)
• Automotive MEMS Pressure Sensors (2)
• Automotive MEMS Pressure Sensors (3)
• Automotive MEMS Pressure Sensor Application Solutions
• 7.7 TDK
• Automotive Sensor Layout
• Key Automotive MEMS Sensor Processes
• Automotive MEMS IMU Application Scenarios
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS Pressure Sensor Application Solutions
• Automotive MEMS Microphones
• 7.8 Murata
• Automotive Sensor Layout
• Automotive MEMS Sensor Application Scenarios and Product Selection
• Key Automotive MEMS Sensor Processes (1)
• Key Automotive MEMS Sensor Processes (2)
• Key Automotive MEMS Sensor Processes (3)
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS Sensors (3)
• 7.9 Sensata
• Automotive Sensor Lineup
• Automotive MEMS Pressure Sensor Layout
• Sensor Application Layout in BEVs
• Sensor Application Layout in PHEVs
• Sensor Application Layout in Electric Commercial Vehicles
• Automotive MEMS Pressure Sensor Application Solutions (1)
• Automotive MEMS Pressure Sensor Application Solutions (2)
• Automotive MEMS Pressure Sensor Application Solutions (3)
• 7.10 Panasonic
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS IMU Application Solutions (1)
• Automotive MEMS IMU Application Solutions (2)

8 Chinese Automotive MEMS Sensor Suppliers

• 8.1 Anhui XDLK Microsystem
• MEMS Sensor Layout
• MEMS Sensor Application Scenarios
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Sensors
• 8.2 NOVOSENSE
• Automotive Sensor Solutions
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS Sensors (3)
• Automotive MEMS Pressure Sensor Application Solutions (1)
• Automotive MEMS Pressure Sensor Application Solutions (2)
• 8.3 Ampron
• Sensor Layout
• Automotive MEMS Sensor Classification and Application Scenarios
• Key Automotive MEMS Sensor Processes
• Automotive MEMS Sensor Customers
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Pressure Sensors (1)
• Automotive MEMS Pressure Sensors (2)
• 8.4 QST
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS IMUs (1)
• Automotive MEMS IMUs (2)
• 8.5 MiraMEMS
• Key Automotive MEMS Sensor Processes
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Sensors
• 8.6 AAC Technologies
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS Sensors (3)
• 8.7 MEMSIC
• Automotive Application Solutions
• Key Automotive MEMS Sensor Processes (1)
• Key Automotive MEMS Sensor Processes (2)
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Sensors
• Automotive MEMS Acceleration Sensor Application Solutions
• 8.8 MT Microsystems
• Automotive Sensor Layout
• Key Automotive MEMS Pressure Sensor Processes
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Sensors
• Automotive MEMS Sensor Application Solutions
• 8.9 MEMSensing
• Key Automotive MEMS Pressure Sensor Processes
• Automotive MEMS Sensors: Summary of Products and Functional Features (1)
• Automotive MEMS Sensors: Summary of Products and Functional Features (2)
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• 8.10 Asensing Technology
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• 8.11 Huaxin Semiconductor
• Automotive MEMS Sensors: Summary of Products and Functional Features
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• Automotive MEMS Sensors (3)
• 8.12 Rsentech
• MEMS Automotive Sensors (1)
• MEMS Automotive Sensors (2)
• 8.13 Winsen
• Automotive Sensor Layout
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• 8.14 ASAIR
• Smart Traffic Sensor Solutions
• Automotive MEMS Sensors (1)
• Automotive MEMS Sensors (2)
• 8.15 NationalChip
• Automotive MEMS Sensors