Learn about opportunities for low voltage motors in major appliances, small appliances and power tools. Understand power stage architectures, topologies and control methods for low voltage brushed DC, stepper and brushless DC motors as well as the system design aspects, challenges and solutions.
Learn the opportunities of motor drives in appliances and understand why there is clear transformation happening from high voltage to low voltage motor drives
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 the design challenges for the power stage in a low voltage BLDC motor drive and understand the system solutions enabling high efficient, robust and reliable system. Also learn about different power supply solutions for low voltage motor control.
Learn about TI 3D depth sensing technology and implementation for industrial, automotive and consumer applications including gesture control, 3D scanning, robotic navigation, augmented reality and people counting. For additional information about 3D time-of-flight technology and design resources, please visit ti.com/3dtof.
Modern battery powered motor drive applications such as power tools, drones, vacuum cleaners, eBikes, etc. show a clear trend towards permanent magnet synchronous motors (PMSM) and brushless DC motors (BLDC). The biggest challenge in designing the power stage for these applications is to meet form factor, efficiency, protection, peak current carrying capability and thermal performance. This training will explain how to do a system design to meet the design challenges by proper selection of power FET and gate driver.
Applications Engineer Jason Tao discusses PFC basics, topology comparisons and design considerations to achieve a cost-optimized and efficient PFC design.
The mmWave training curriculum provides foundational content and hands on examples for you to learn the fundamentals of FMCW technology and mmWave sensors, and start development quickly. TI's portfolio of mmWave sensors features the AWR automotive radar sensor family and the IWR industrial mmWave sensor family, which are intended to be used for detecting range, velocity and angle of objects. Learn more about the silicon, tools, software and some of the applications for both mmWave families in the mmWave training series.
New to mm-wave sensing? This series of five short videos provides a concise yet in-depth introduction to sensing using FMCW radars.
Labs are follow-along training videos that walk you through installation, building, and running examples of mmWave sensor projects.
All the content from the 4-part webinar series launched last November 2018 is now available as an open source in our Training Portal for all of the users interested in the motor drives and control topic.