Accelerated Development of AURIX Motor Drives and xEV Powertrains through Advanced High-Fidelity Simulator
In an exciting development for the automotive industry, Infineon Technologies and Typhoon HIL have joined forces to deliver a cutting-edge real-time development and testing environment for electric vehicle (xEV) powertrain systems. This collaboration aims to streamline the development process, improve safety, and boost confidence in the design of xEV powertrains.
At the heart of this partnership is the Infineon AURIX TC3x/TC4x automotive microcontrollers (MCUs), which are integrated with Typhoon HIL's advanced simulation technology. This integration offers robust testing for critical powertrain functions such as battery management, inverter control, and motor drive systems, thereby enhancing system reliability and safety.
Key features of this partnership include a complete hardware-in-the-loop (HIL) simulation and test solution tailored for Infineon’s AURIX TC3x/TC4x MCUs. This solution supports rapid development, validation, and optimization of xEV powertrain electronics. It also boasts real-time, high-fidelity simulation capabilities that enable engineers to test power electronic systems and control algorithms under realistic conditions without requiring physical prototypes, thereby accelerating development cycles.
The benefits of this collaboration are manifold. It accelerates xEV powertrain development by enabling early-stage model-based design verification and validation, significantly reducing time-to-market. It improves the accuracy and scalability of testing for complex electrified vehicle power systems, lowering engineering costs and risks associated with hardware testing. The partnership also supports automotive safety standards by providing a deterministic testing environment that can simulate fault conditions and edge cases, thus ensuring more robust designs.
Moreover, the collaboration enhances developer productivity through dedicated evaluation boards and software tools facilitating seamless integration and workflow optimization. The solution can be used with Infineon's TriBoard Interface Card, which supports AURIX TC3xx and TC4xx evaluation boards. Designed to streamline validation workflows, this card expedites design and testing processes.
Typhoon HIL also offers an "Automotive Communication Extender" product for its HIL Simulator solution based on an AURIX TC3xx processor. This extender provides an enhanced communication interface for connecting to a larger number of heterogeneous electronic control units (ECUs) under test via CAN, CAN FD, LIN, and SPI protocols.
In conclusion, the Infineon and Typhoon HIL partnership provides a comprehensive, industry-grade real-time HIL platform that empowers automotive engineers to develop, test, and validate xEV powertrain systems more efficiently, safely, and with higher confidence. This collaboration is set to revolutionize the landscape of embedded design, particularly in the realm of electric vehicles, and contribute to a sustainable future.
- This industry-grade real-time HIL platform, resulting from the collaboration between Infineon Technologies and Typhoon HIL, is expected to have a significant impact on the finance sector by potentially reducing engineering costs and risks associated with hardware testing, thereby minimizing expenditure for xEV powertrain development.
- With the integration of Infineon's AURIX TC3x/TC4x automotive microcontrollers and Typhoon HIL's advanced simulation technology, the technology sector stands to benefit as data-and-cloud-computing capabilities are improved through enhanced simulation technologies, delivering more realistic testing scenarios for power electronic systems and control algorithms.
- The automotive industry is likely to witness a transformation in transportation as the Infineon and Typhoon HIL partnership provides a more efficient, reliable, and safe development and testing environment for electric vehicle (xEV) powertrains, contributing to advancements in electric vehicle technology and aiding the industry's transition towards cleaner and more sustainable energy sources.
