New RH850/V1R Microcontroller Series Delivers High Computing and Optimized Digital Signal Processing to Enable Higher Accuracy and Safety for Radar-Based Applications
04 Jan 2017
Software and tools including evaluation boards will also become available to enable the system developers to start their development immediately with the RH850/V1R-M solution.
With the expansion of ADAS and autonomous driving, sensors are fast becoming a key technology. Currently vehicles are being equipped with a broad spectrum of sensors such as cameras, lidar and ultrasonic sensors. In particular, radar sensors are required for ADAS applications, including advanced emergency braking and adaptive cruise control, because, unlike other sensors, radar sensors are not negatively affected by external environmental limitations which includes adverse weather conditions, such as rain, fog or whether the sun is shining or not.
Additionally, high precision sensing becomes critical in realizing future autonomous driving to meet the increasing requirements of range resolution, separation of objects and precision in measurement of velocity. This requires increased numbers of antennas and boosting of the signal processing performance.
To address these needs, Renesas launched the new RH850/V1R-M MCU specifically designed for radar applications in ADAS. The new MCU includes optimized, programmable digital signal processing, a dual core at 320 megahertz (MHz) with industry-leading high speed flash of 2 megabyte (MB), a 2 MB internal RAM, while meeting the industry's highest temperature requirements.
Key features of the RH850/V1R-M MCU:
(1) High-performance DSP with flexible programmability for improved radar signal processing performance and increased sensing accuracy
The RH850/V1R-M MCU is designed to have optimized hardware acceleration in the DSP. The optimized DSP allows the system developers to process the raw data into target objects efficiently, separately from the safety relevant classification and tracking done in the CPUs. Renesas’ high performance DSP performs radar specific algorithms such as fast fourier transforms (FFTs, Note 2), beamforming, windowing, channel calibration, peak search, at high speed and with low power consumption. The DSP offers high flexible programmability and Renesas specifically developed a DSP math library for automotive radar sensors to support system developers in their algorithm development.
(2) Renesas low-power technology and embedded flash for more compact and low-cost radar sensors
The RH850/V1R-M is developed using Renesas’ world leading 40-nanometer (nm) embedded flash (eFlash) process technology, which has a proven track record in terms of re-write cycles, the industry’s fastest random access operation speeds and high reliability. It also has the merit of low power consumption as the transistors are smaller lowering parasitic capacitances.
The process specification of RH850/V1R-M also fulfills the highest temperature requirements in the industry (T-junction 150°C).
The embedded flash brings advantage to the system designer by offering higher integration using less PCB space and better real time behavior.
(3) Dual core at 320MHz high performance, integrated 2MB large capacity RAM, 2MB highest speed flash and highest temperature requirements
The new RH850/V1R-M features two G3MH CPU cores operating at 320 megahertz (MHz) and are the highest performance cores among the RH850 Family. The G3MH is a superscalar reduced instruction set computer (RISC) architecture with two 7-stage integer pipelines, which allows execution of two different instructions at the same time. Each G3MH core achieves the performance of 3.2 DMIPS/MHz (Note 3).
The RH850/V1R-M also includes 2MB industry-highest speed flash based on Renesas world-leading automotive 40nm embedded flash technology.
By incorporating a large 2MB capacity RAM, the RH850/V1R-M handles all specific calculations on radar cube data such as range and velocity FFTs, digital beam forming, constant false alarm rate (CFAR, Note 4) and peak detection.
Pricing and Availability
Samples of the RH850/V1R-M and the DSP math library will be available from second half of 2017. Samples will be priced at US$30 per unit. Mass production is scheduled to begin in November 2018. A flexible programmable complete toolchain with C/C++ compiler, debugger, simulation models and detailed performance profiling tools will also be available. (Pricing and availability are subject to change without notice.)
YouTube videos about Renesas’ commitment to ADAS and Autonomous Drive and Renesas Radar Solution RH850/V1R-M are available here:
- Renesas’ commitment to ADAS and Autonomous Drive
- Renesas Radar Solution RH850/V1R-M
Refer to the separate sheet (PDF: 165 KB) for specifications of the RH850/V1R-M MCU.
(Note 1) Digital signal processing (DSP):
Refers to various mathematical techniques applied to process a signal.
(Note 2) Fast Fourier transform (FFT):
An algorithm for computing that converts a signal from its original domain to a representation in the frequency domain.
(Note 3) DMIPS (Dhrystone million instructions per second):
An index of computing performance calculated using the Dhrystone benchmark program.
(Note 4) Constant false alarm rate (CFAR):
CFAR detection refers to adaptive algorithms used in radar applications to detect target returns against a background of noise.
About Renesas Electronics Corporation
Renesas Electronics Corporation (TSE: 6723) delivers trusted embedded design innovation with complete semiconductor solutions that enable billions of connected, intelligent devices to enhance the way people work and live. A global leader in microcontrollers, analog, power, and SoC products, Renesas provides comprehensive solutions for a broad range of automotive, industrial, home electronics, office automation, and information communication technology applications that help shape a limitless future. Learn more at renesas.com.
The content in the press release, including, but not limited to, product prices and specifications, is based on the information as of the date indicated on the document, but may be subject to change without prior notice.