As the number of complex electronic features in vehicles increase, body control modules (BCMs) are rapidly evolving to keep up. All semiconductor devices in a BCM have one thing in common – they all need power. This training series will go over the various power topologies needed in a BCM in a vehicle.
Learn the different power stage architectures and topologies for low voltage brushed DC and stepper motor drives and understand typical system design challenges and differentiated solutions from Texas Instruments.
Learn the different power stage architectures and topologies for low voltage brushless DC motor drives and understand typical design challenges and differentiated solutions with integrated motor drivers.
Learn about sub-system blocks and trends in Building Automation systems design
This training is meant for engineers designing the control circuits for servo or AC inverter motor controllers for industrial machinery. In particular, the on-demand curriculum is for those who are planning to develop their next drive system based on a C2000™ microcontroller (MCU) and are interested in quickly learning how to use the DesignDRIVE solutions available from TI.
This section contains training on DesignDRIVE current loop control innovations.
An introduction to the new DesignDRIVE Position Manager technology for TMS320F28379D and TMS320F28379S Delfino™ real-time controllers. Position Manager provides solutions for interfacing to servo motor rotor absolute position sensors such as resolvers, SIN/COS, EnDat 2.2 and BiSS-C.
C2000 MCU DesignDRIVE, a new evaluation platform to explore numerous industrial drive subsystems and motor control topologies. This evaluation platform supports various motor types, current sensing technologies and position sensors.
Learn how C2000 devices excel in sensing and DSP processing applications.
This module discusses discrete implementation typically seen inside automotive body control module to monitor external switches. Common implementation methodology is reviewed in this section, and some of the challenges using discrete implementation is discussed in detail.
Both isolated modulator and isolated metrology AFE architectures have their advantages with respect to each other. Depending on system requirements, one architecture may be more feasible than the other. This section compares the two isolated shunt sensing architectures and discusses which architecture is best for different system requirements.