Advanced driver assistance system (ADAS) applications—essential for enhancing the driver experience and overall safety—are one of the fastest growing segments of the automotive semiconductor space. However, ADAS applications require a performance level that goes far beyond popular microcontrollers, which is leading to major disruptions in the automotive industry. Hence a new class of high-performance SoC is needed to process all sensor data and fuse them together.
High-performance ADAS SoC requirements include:
- High-compute performance: 1TMAC/sec in <1mm2 to support a digital signal processing architecture tuned to process compute-intensive algorithms, delivering an optimal SoC performance, power, and area (PPA) ratio
- Machine learning: Dedicated optimized and fully programable neural network processor cores
- High memory bandwidth: >3Gbit/s data-rate interfaces and sufficient memory space required to store and access intermediate results generated by highly complex algorithms
- High network bandwidth: 1Gbit/s or more to support a low-latency transmission of high video/image resolution or control data
- Low power consumption: <9W power consumption for ADAS applications
- Safety: Safety architecture including documentation to support ISO 26262-compliant system development
- Security: Protect safety-critical data against manipulation
Cadence® Tensilica® customizable processors scale from small efficient controllers up to compute-intensive data processing engines. The high-performance, low-power DSPs are ASIL-B-ready certified and perfectly suited for automotive applications like vision, radar, lidar, infotainment, Car2X, and more.
Imaging and Computer Vision Processing
In order to make cars safer and more comfortable, ADAS applications are becoming more and more popular. The huge amount of data generated by these systems—up to 1Gbyte/s (4TByte/day)—requires very powerful data-processing platforms with AI acceleration.
Tensilica DSPs can help to efficiently offload the host CPU and accelerate the sensor data processing to significantly reduce the power consumption. Imaging and vision algorithms can run on a DSP that’s specifically optimized for the imaging and vision functions. Regardless of the ADAS application, the Tensilica DSP can be leveraged in the sensor itself, within the ADAS electronic control unit (ECU), or in the central sensor fusion platform.
On-Device AI Processing
However, regardless of the sensor type, a machine needs to efficiently analyze the data and reliably recognize objects. Recently neural networks have become very popular for this task, enabling high object-recognition rates of more than 99%. However current solutions based on CPUs or GPUs consume too much power and therefore cannot be used in production cars.
Two key things must be provided for the efficient deployment of neural networks:
- A scalable, low-power multi-core hardware platform that is fully programmable
- A development software flow that automatically optimizes and maps neural networks on the target platform
Our Tensilica DNA 100 processor is well suited for on-device neural network inference applications spanning autonomous vehicles (AVs), ADAS, surveillance, robotics, drones, augmented reality (AR), virtual reality (VR), smartphones, smart homes, and IoT.
The DNA 100 processor delivers up to 4.7X better performance and up to 2.3X more performance per watt compared to other solutions with similar multiplier-accumulator (MAC) array sizes.
Tensilica Neural Network Compiler
Radar, Lidar, and Communications
From the dual- or quad-MAC Fusion F1 DSP up to the super-high-performance 128-MAC ConnX B20, these Tensilica DSPs are designed for a broad range of applications that control sensors and antennas and process the data they handle.
The Tensilica Fusion and ConnX DSP families are the industry's lowest power, most compact, and best performing DSPs for applications including radar, lidar, 5G, 4G/LTE-A, Bluetooth, smartgrid, and 802.11 modems. Cadence offers several pre-designed, pre-verified DSPs to accelerate the design effort and time to market. Learn More
- Automotive Sensors: Concepts and Trends
- Whiteboard Wednesdays - Tensilica DSPs, Sensors, and Neural Networks
- Dream CHIP Technologies – Automotive ADAS Chip Architecture
- AI-based Pedestrian Detection powered by Cadence Tensilica
- Introduction to ADAS with a Real-Life Example
- AI for Image Classification and Object Detection
- Full HD 360° Surround View enabled by Tensilica Vision P6 DSP
- Protium S1 used to prototype a pedestrian detection application.
- AI for People Detection using Tensilica Vision P6 DSP
- Breaking Down ADAS Sensor Fusion Platforms and Sensor Concepts
- Low Power Embedded CNN with Tensilica High-Performance Vision DSP
- Renesas: Balancing Performance, Low-Power and Functional Safety in ADAS Applications
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