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The LAUNCHXL-F28P65X is a low-cost development board for the Texas Instruments C2000 RealTime Microcontroller series of F28P65x devices.

A traction inverter converts the EV battery’s high-voltage DC to the AC that the electric motor needs. The traction inverter controls the speed and torque of the motor, and its efficiency has a direct impact on the power and thermal dissipation, as well the EV’s driving range.

Development kit for rapid prototyping featuring the TMS320F28P650DK9 microcontroller.

The UCC21732 is a galvanic isolated single channel gate driver designed for SiC MOSFETs and IGBTs up to 2121V DC operating voltage with advanced protection features, best-in-class dynamic performance and robustness. The UCC21732 has up to ±10A peak source and sink current.

Up to 2× Dual-core Arm Cortex-R5F MCU subsystems operating at up to 800 MHz, highly integrated for real-time processing.

The BQ79616 device provides high-accuracy cell voltage measurements in less than 200 μs for 16-series battery modules in high-voltage battery management systems in HEV/EV. The monitor offers different channel options in the same package type, providing pin-to-pin compatibility and supporting high reuse of the established software and hardware across any platform.

Motor drives are an integral part of industrial and automation processes. These processes often involve the control of machinery, for which safety is always a concern

Motor applications that sustain higher power ratings introduce design considerations that are not required in lower power applications.

As electric vehicles (EVs) become more popular, the challenge for automakers is to reflect true range while making the vehicle more affordable. This translates into making the battery packs lower cost with higher energy densities. Every single watt-hour stored and retrieved from the cells is critical to extend the driving range.

PCB design of motor drive systems is not trivial and requires special considerations and techniques to achieve the best performance. Power efficiency, high-speed switching frequency, low-noise jitter, and compact board design are few primary factors that designers must consider when laying out a motor drive system.