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Global and China Automotive Millimeter-wave (MMW) Radar Industry Report, 2019-2020

  • ID: 5021656
  • Report
  • April 2020
  • Region: Global, China
  • 240 pages
  • Research In China


  • ADI
  • Bosch
  • Geely
  • Linpowave
  • Nullmax
  • Uhnder
Millimeter wave radar installations soared by 44.37% year-on-year in 2019 and were available in more scenarios, encroaching on Lidar and ultrasonic.

Automotive radar wins popularity and gets increasingly installed. In 2019, 5.17 million mm-wave radars were installed in passenger cars in the Chinese market with an annualized spurt of 44.37%, particularly 77GHz radar installations with an upsurge of 69.3% from a year earlier.

Chinese carmakers have more radar installations than joint venture brands. For the newly launched models, Geely Geometry, WM Motor, BAIC ARCFOX, Chang’an, SAIC Roewe/MAXUS, FAW Hongqi, Xpeng and other homegrown brands all emphasize L2/L2.5/L3 autonomous driving technology and install more sensors including mm-wave radar.

Well-known radar suppliers are promoting 77GHz radar vigorously, like the latest generation of medium- and long-range 77GHz radar launched by Bosch and Continental, and at the same time famous radar chip makers are mostly rolling out the 77GHz-centric chip generally in favor of the high modulation bandwidth 2GHz and with 3 transmitters and 4 receivers to detect farther.

The upcoming RXS816xPL is a highly integrated device that addresses the needs of 77-79 GHz radar for all safety-critical applications from automatic emergency-braking (AEB) to high-resolution radar in automated driving and that performs all functions of a radar front-end in a single device - from FMCW signal conditioning to generation of digital receive data output. It resorts to high modulation bandwidth 2 GHz to realize precise distance measurement and simultaneous transmitter operation for MIMO, capable of detecting and identifying objects within 300 meters.

Texas Instruments plans to launch the 77GHz AWR2243, an integrated single-chip FMCW transceiver working in the 76- to 81-GHz band. The device has a tiny footprint and unprecedented integration and supports 5G bandwidth. Simple programming model changes enable a wide variety of sensor implementation (short, medium, long range). Additionally, the device is provided as a complete platform solution to reduce development costs.

MMW radar chip vendors have released suitable chips for more applications, especially in ultra-short range and short range.

Radar finds wider applications in scenarios like cockpit and occupant monitoring, automated parking, collaborative vehicle infrastructure system (CVIS) and intelligent transportation with the help of radar chips.

Cockpit and Occupant Monitoring

Vayyar Imaging, an Israeli provider of radar imaging sensor technology, said in November 2019 it raised $109 million in a Series D funding led by Koch Disruptive Technologies, bringing its total raised to-date to $188 million. In the automotive domain, Vayyar claims its chip enables in-cabin passenger location and classification, occupant size, vital sign and posture analysis, as well as 360° exterior mapping, including monitoring cars, objects and pedestrians around a vehicle, in all lighting and weather conditions, and in real time. At the 2018 Paris Motor Show, Valeo indeed announced it was integrating Vayyar’s radar sensors with its products to monitor infants’ breathing and trigger an alert in case of emergency. Brose and Vayyar collaborate on sensor technology for new door and interior functions. Sensors recognize occupancy in the interior at all times to ensure the necessary level of safety in the interaction of mechanical and electronic systems. These sensors will also make it possible for side doors to open and close automatically and if other vehicles or obstacles are in the way, the movement ends before the door comes into contact with any object.

For L2, L3 and L4 autonomous driving, occupant monitoring is of growing importance. Autonomous vehicle interiors are fairly flexible, like sliding seats, screens and consoles, suitable for work and relaxation. The short-range radar and visual sensors work together to identify the situation in the car in real time, and the mechanical and electronic systems interact to ensure the safety.

Automated Parking

In December 2019, ZongMu Technology released in Xiamen city the second-generation autonomous parking product -- AVP Gen.2 that has main sensors including four fisheye cameras, 12 ultrasonic sensors, and four 4D MMW radars.

When all of four surround-view cameras are blocked and only mm-wave radar is available, AVP Gen. 2 can still fully implement AVP because the radar can deliver the dense point cloud information comparable to that of Lidar and clearly outline the surrounding buildings to achieve high-precision localization based on radar point clouds.

The radar used by AVP Gen.2 is called SDR1, which gets specially optimized in the typical parking scenarios (underground/ground parking lots, parks, etc.) on the basis of traditional angle radar ADAS functions to perfectly meet all parking needs. SDR1 takes into account both of low-speed parking scenarios and high-speed ADAS, and can work under extreme conditions such as wind, heavy snow, night, etc. The product will be spawned in the fourth quarter of 2020.

CVIS and Intelligent Transportation

In April 2020, Muniu Tech rolled out three WAYV-branded radars: WAYV Air, WAYV and WAYV Pro. WAYV includes T300 and S300, which are used in intelligent transportation and intelligent security respectively. WAYV Pro breaks the detection distance limit of video and infrared sensors to reach 1,000 meters, ideal for highway accident monitoring and large-area security.

With a detection range of 300 meters, Wayv T300 covers 8 lanes, detects and tracks 128 objects simultaneously, mainly serving urban traffic data perception and planning. Wayv T1000 works at a maximum distance of 1,000 meters, suitable for long-distance and highway deployment. It can detect and track 256 objects on 10 lanes simultaneously.

Market Shares of Lidar and Ultrasonic Radar Are Squeezed

Millimeter-wave radar is developing radically, with the imaging radar as an alternative to Lidar and the ultra-short-range radar as a substitute for ultrasonic.

The thriving angle radar has lured mm-wave radar vendors to develop ultra-short-range solutions for parking, AEB and short-range blind spot detection as the alternative of traditional ultrasonic sensors.

With far better performance than ultrasonic sensors on the market, the Autus R10 chip of MediaTek offers a wider detection range. Other than distance information, it can also provide speed information while ultrasonic does not. The Autus R10 chip can be used for multiple applications including blind spot detection (BSD), parking assist system (PAS), automatic parking assistance (APA), rear automatic emergency braking, cross-traffic alerts, door opening alerts and ultra-short-range BSD.

The most cost-effective ultrasonic sensor has a slow response to object detection, and it cannot classify objects into human and non-human, while mm-wave radar can perform object classification and biometric monitoring.

Many chip vendors, including traditional radar chip giants such as NXP, TI and Infineon, have launched solutions that shore up high-resolution radar. High-resolution imaging radar will outperform Lidar in terms of cost and performance. In some cases, imaging radar may identify objects such as bicycles, pedestrians, or small obstacles on the road and it also can deal with severe weather conditions.

Lidar will be replaced by Camera + imaging MMW Radar + V2X, said by Lars Reger, CTO of the NXP Semiconductors Automotive Division. The focus of the collaboration between NXP and HawkEye Technology is to create high-resolution imaging radar.

MMW Radar Boosts the Plasticization of Automotive Exterior Parts

Radars are generally fixed behind the car logo or the grille, and integrated into the lights, roof, etc. Millimeter wave radar detects the object, distance, speed and position by emitting electromagnetic waves, which are extremely sensitive to metals, and detecting echoes. In the traditional design, car head and door panels mostly made of metal cannot hide the radar.

Radars must come with plastic peripheral parts whose electrolyte conductivity should be low, especially the materials cannot contain carbon fiber or metals with electronic shielding effect. Covestro, BASF, Lotte, Orinko, Sumitomo, Mitsubishi and the like have developed wave-transparent materials PC, PP, ABS and so on for automotive exterior parts.
Note: Product cover images may vary from those shown


  • ADI
  • Bosch
  • Geely
  • Linpowave
  • Nullmax
  • Uhnder

1 MMW Radar Technology
1.1 Introduction to Automotive MMW Radar
1.2 Development Course of Automotive Radar
1.3 Advantages of Automotive MMW Radar
1.4 Frequency of Automotive MMW Radar
1.4.1 Characteristics of Different Frequencies
1.4.2 Frequency Comparison
1.5 Classification and Technology Trends of Automotive MMW Radar
1.5.1 Classification
1.5.2 Main Spectrum Technology Roadmaps by Country
1.5.3 Spectrum Trends
1.5.4 Application Trends
1.5.5 New Development-4D Radar
1.6 Working Mechanism and Composition
1.6.1 Working Mechanism and Product Application
1.6.2 Core Component-MMIC
1.6.3 Core Component-Antenna PCB
1.7 Automotive MMW Radar Supply Chain
1.7.1 Supply Chain: Multinational Companies
1.7.2 Supply Chain: Chinese Companies

2 Automotive MMW Radar Market

2.1 Status Quo of Chinese Automotive Market
2.1.1 Status Quo of Chinese Passenger Car Market
2.2 MMW Radar Installations in Chinese Passenger Car Market
2.3 MMW Radar Penetration Rate in Chinese Passenger Car Market, Jan 2018-Dec 2019
2.4 MMW Radar Installations Per Vehicle in Chinese Passenger Car Market, Jan 2018-Dec 2019
2.5 24GHz MMW Radar Installations in Chinese Passenger Car Market, Jan 2018-Dec 2019
2.6 Top 20 Brands in Chinese Passenger Car Market by 24GHz MMW Radar Installations, 2019
2.7 Top 20 Brands in Chinese Passenger Car Market by 24GHz MMW Radar Installation Rate, 2019
2.8 77GHz MMW Radar Installations in Chinese Passenger Car Market, Jan 2018-Dec 2019
2.9 Top 20 Brands in Chinese Passenger Car Market by 77GHz MMW Radar Installations, 2019
2.10 Top 20 Brands in Chinese Passenger Car Market by 77GHz MMW Radar Installation Rate, 2019
2.11 ADAS-use MMW Radar Trends in Chinese Passenger Car Market, Jan 2018-Dec 2019
2.12 Installations in Chinese Passenger Car MMW Radar Market, 2016-2022E
2.13 Chinese Passenger Car MMW Radar Market Size, 2016-2022E
2.14 Market Share of 24/77GHz MMW Radar in Chinese Passenger Car Market
2.15 Forecast for Chinese Passenger Car MMW Radar Market Size (24GHz / 77GHz)

3 Development Trends of MMW Radar Industry

3.1 Developments of Automotive MMW Radar Industry
3.1.1 Products / Financing
3.1.2 Market Application
3.2 Trends of Automotive MMW Radar
3.2.1 Andar
3.2.2 Shanghai Baolong Automotive Corporation
3.2.3 Calterah Semiconductor
3.2.4 Nanoradar Science &Technology
3.2.5 MiSic Microelectronics
3.2.6 ZongMu Technology
3.2.7 Arbe
3.3 Application Trends of Automotive MMW Radar
3.3.1 Automaker: Geely
3.3.2 Automaker: WM Motor
3.3.3 Automaker: FAW Hongqi
3.3.4 Automaker: NextEV
3.3.5 Automaker: SAIC
3.3.6 Automaker: Xpeng
3.3.7 Solution Provider: Nullmax
3.3.8 Solution Provider: Autobrain
3.3.9 Solution Provider: Momenta

4 Global MMW Radar Vendors

4.1 Comparison of Foreign MMW Radar Companies and Products
4.1.1 Major Foreign MMW Radar Suppliers
4.1.2 Parameter Comparison of Typical Foreign MMW Radars
4.1.3 Parameter Comparison of Typical Foreign MMW Radars
4.2 Continental
4.2.1 Profile
4.2.2 ADAS Products
4.2.3 5th-Gen 77GHz MMW Radar
4.2.4 The Latest MMW Radar
4.2.5 Radar and Lidar Customers
4.3 Bosch
4.3.1 Profile
4.3.2 Operation in 2019
4.3.3 Chassis Control and Radar Product Layout
4.3.4 Introduction to 5th-Gen 77GHz MMW Radar
4.3.5 Technical Parameters of 5th-Gen 77GHz MMW Radar
4.3.6 Technical Solutions for Autonomous Driving Hardware
4.3.7 Sensors Required by Autonomous Driving (including MMW Radar)
4.3.8 MMW Radar for Positioning System
4.4 ZF
4.5 Aptiv
4.6 Veoneer
4.7 Denso
4.7.1 Profile
4.7.2 Operation in 2019
4.7.3 77GHz MMW Radar
4.7.4 Autonomous Driving Investment and R & D Layout
4.7.5 Automotive MMW Radar Investment
4.7.6 Profile of Denso Ten
4.7.7 MMW Radar of Denso Ten
4.8 Valeo
4.9 Hella
4.9.1 Profile
4.9.2 Operation in 2019
4.9.2 24GHz MMW Radar
4.9.3 Brand New 77GHz MMW Radar
4.9.4 Autonomous Driving Development Roadmap
4.9.5 Autonomous Driving Partners and Cooperation Fields
4.10 Comparison of Major Foreign MMW Radar Vendors

5 Chinese MMW Radar Companies
5.1 Comparison of Radar Vendors and Products
5.1.1 MMW Radar Suppliers
5.1.2 Parameter Comparison of Typical MMW Radars
5.1.8 Parameter Comparison of Typical MMW Radars
5.1.9 Comparison of Major MMW Radar Vendors
5.2 WHST (Wuhu Sensortech)
5.2.1 Profile
5.2.2 Automotive MMW Radar
5.2.3 Recent Developments
5.2.4 Development Trends of Automotive Radar
5.3 Autoroad
5.3.1 Profile
5.3.2 Product Layout
5.3.3 Latest Products
5.3.4 Automotive Radar Roadmap
5.4 Intibeam
5.4.1 Profile
5.4.2 24GHz Blind Spot Radar and 77GHz Anti-collision Radar
5.4.3 79GHz High-resolution MMW Radar
5.4.4 Automotive Radar Roadmap
5.5 Muniu Tech
5.5.1 Profile
5.5.2 Automotive Radar Positioning
5.5.3 Main Products
5.5.4 Latest Trends
5.6 Nanoradar Science &Technology
5.6.1 Profile
5.6.2 Development Course
5.6.3 Main Products
5.7 Morgina
5.7.1 Profile
5.8 Suzhou Millimeter-wave Technology Co., Ltd.
5.8.1 Profile
5.8.2 Development Strategy
5.8.3 Main Products
5.8.4 Project Progress
5.9 HawkEye Technology
5.9.1 Profile
5.9.2 Recent Developments
5.10.1 Profile
5.10.2 Main Products and Latest Progress
5.11 Linpowave
5.12 TransMirowave
5.12.1 Profile
5.12.2 Corporate Structure & Development Course
5.12.3 Automotive MMW Radar
5.13 Xuanyuan Idrive
5.13.1 Profile
5.13.2 Blind Spot Detection System
5.14 Raco
5.14.1 Profile
5.14.2 Development Course
5.15 Oculii
5.15.1 Profile
5.15.2 4D Radar
5.15.3 Products and Latest Trends
5.16 Chuhang Tech
5.16.1 Profile
5.16.2 Development Course
5.16.3 R & D and Production Layout
5.16.4 Main Products
5.16.5 Core Products and Technologies
5.16.6 Major Customers and Cases
5.16.7 Products and Technology Roadmap
5.16.8 Development Strategy and Planning
5.17 Microbrain Intelligent
5.17.1 Profile
5.17.2 Intelligent Autonomous Driving Solution
5.17.3 MMW Radar
5.18 Huayu Automotive Systems
5.18.1 Profile
5.18.2 Operating Performance and MMW Radar R & D
5.18.3 Autonomous Driving Layout
5.18.4 MMW Radar Application Cases

6 MMW Radar Chip Vendors
6.1 Infineon
6.1.1 Profile
6.1.2 Operation in 2019
6.1.3 24GHz Radar Chip
6.1.4 24GHz MMW Radar Chip Product System and Performance
6.1.5 77GHz Radar Chip
6.1.6 77GHz Radar Chip Application
6.1.7 Upcoming Radar Chip
6.2 NXP
6.2.1 Profile
6.2.2 Operating Results
6.2.3 Main Products
6.3 STMicroelectronics
6.3.1 Profile
6.3.2 Operating Results
6.3.3 MMW Radar
6.4.1 Profile
6.4.2 MMIC
6.4.3 Solutions
6.4.4 Development Course
6.5 Calterah Semiconductor
6.5.1 Profile
6.5.2 77GHz Radar Transceiver Chip and Application
6.5.3 Latest Trends
6.6 ADI
6.7 Uhnder

Note: Product cover images may vary from those shown
  • Andar
  • Shanghai Baolong Automotive Corporation
  • Calterah Semiconductor
  • Nanoradar Science &Technology
  • MiSic Microelectronics
  • ZongMu Technology
  • Arbe
  • Geely
  • WM Motor
  • FAW Hongqi
  • NextEV
  • SAIC
  • Xpeng
  • Nullmax
  • Autobrain
  • Momenta
  • Continental
  • Bosch
  • ZF
  • Aptiv
  • Veoneer
  • Denso
  • Valeo
  • Hella
  • WHST (Wuhu Sensortech)
  • Autoroad
  • Intibeam
  • Muniu Tech
  • Nanoradar Science &Technology
  • Morgina
  • Suzhou Millimeter-wave Technology Co., Ltd.
  • HawkEye Technology
  • Linpowave
  • TransMirowave
  • Xuanyuan Idrive
  • Raco
  • Oculii
  • Chuhang Tech
  • Microbrain Intelligent
  • Huayu Automotive Systems
  • Infineon
  • NXP
  • STMicroelectronics
  • Calterah Semiconductor
  • ADI
  • Uhnder
Note: Product cover images may vary from those shown