Voltage supervisors increase the system reliability and robustness by ensuring that power rails are active only during stable power supply. This is achieved through functions such as: precise voltage monitoring, over-voltage protection, power failure indicator, processor monitoring, power sequencing, battery backup, and reset latching.
In this series, you will learn about the:
As processing requirements for electricity meters gradually increase, it becomes increasingly difficult to find one device that meets both the processing requirements for adding advanced metrology features to smart meters while also accurately sensing metrology parameters, such as RMS voltage, RMS current, and active power. To deal with this design challenge, one option is to use a separate metrology microcontroller and a standalone ADC.
As processing requirements for electricity meters gradually increase, it becomes increasingly difficult to find one device that meets both the processing requirements for adding advanced metrology features to smart meters while also accurately sensing metrology parameters, such as RMS voltage, RMS current and active power. To deal with this design challenge, one option is to use a separate metrology microcontroller and a standalone ADC.
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.
Learn about design tips from Texas Instruments' leading power experts to help with all your power design challenges and get you to market faster.
To help explore infinite design possibilities with TI Sitara™ ARM® Processors, Texas Instruments has created the Sitara ARM Processors Boot Camp. This modular training series for TI’s Sitara ARM Processors is based on the latest development kits from TI and provides in-depth technical discussion and hands-on exercises for all aspects of the solution; from architecture to peripherals to software and development environments.
This training series provides an in-depth look at KeyStone multicore SoC devices.
Programmable Real-Time Unit and Industrial Communications Subsystem (PRU-ICSS / PRU-ICSSG) Training Series
The Programmable Real-Time Unit and Industrial Communications Subsystem (PRU-ICSS / PRU-ICSSG) is a small processor that is tightly integrated with an IO subsystem, offering low-latency control of IO pins on TI’s SoC devices including the AM335x, AM437x, AM57x, and AM65x Sitara Processors. The PRU-ICSS / PRU-ICSSG is customer-programmable and can be used to implement simple and flexible control functions, peripherals, and state machines that directly access IO pins of the device, as well as can communicate with the application cores.
TI’s AM6x Sitara processor family, along with the Processor SDK, brings unparalleled scalability, reliability, integration, and ease-of-use to the Sitara product line. The new, highly-integrated Sitara AM6x processor family provides industrial-grade reliability, with quad and dual Arm® Cortex®-A53 core variants built to meet the rapidly evolving needs of Industry 4.0 in factory automation and grid infrastructure.
Similar to existing KeyStone-based SoC devices, the 66AK2Gx enables both the DSP and ARM cores to master all memory and peripherals in the system. This architecture facilitates maximum software flexibility where either DSP- or ARM-centric system designs can be achieved.
This curriculum provides an in-depth look at the K2G Processors, Processor SDK-Linux and TI-RTOS, and the Programmable Realtime Unit (PRU).
TI’s AM57x family, along with the Processor SDK, brings unrivaled integration, scalability, peripherals and ease of use associated with the powerful Sitara processor platform. Sitara AM57x processors' unique heterogeneous architecture including ARM® Cortex®-A15 cores, C66x DSPs, programmable real-time units (PRU), ARM Cortex-M4 cores, and video and graphic accelerators make the AM57x processors unmatched in their class.
TI provides key runtime software components and documentation to further ease development. TI’s online training provides an introduction to the Processor SDK and how to use this software to start building applications on TI embedded processors.
As the entrance of search engine, the explosive growth in wireless speaker or AI speaker is driving the new requirements of audio amplifier - higher efficiency and better audio quality.
Facing these new challenges, TAS5825M (closed loop classD with 38W stereo output) develops a lot of advanced features compared with traditional audio amplifier, which includes:
The TI-RSLK MAX is a low-cost robotics kit and classroom curriculum which provides students with a deeper understanding of how electronic system designs work. Developed with university faculty, Jon Valvano of UT Austin, the TI-RSLK MAX is designed to supplement university curriculum.