Filters in use:
Filters in use:
Filters in use:
Filters in use:
Filters in use:
Sort by:
25 Functions for 25 Cents Video Series
Simple functions such as timer replacement, input/output expanders, system reset controllers and stand-alone EEPROM are common on PCBs. Low-cost, ultra-low-power MSP430™ value line microcontrollers (MCUs) offer cost savings when replacing digital and analog functions in a system. Watch this series to see how MSP430 MCUs can be used to enhance communication, pulse width modulation, systems and housekeeping, and timer functions in your next design.
25 Functions for 25 Cents: Communication Functions
Duration:
25 Functions for 25 Cents: Enhancing Analog and Digital Functions
Duration:
25 Functions for 25 Cents: Pulse Width Modulation Functions
Duration:
25 Functions for 25 Cents: System and Housekeeping Functions
Duration:
25 Functions for 25 Cents: Timer Functions
Duration:
Achieve Precise Measurement for Smoke Detector Designs
Duration:
Adding Bluetooth to MCU-Based Systems
Duration:
Advanced rapid prototyping based on layered Energia code
Duration:
Advanced rapid prototyping based on native USB and MultiBlink
Duration:
Advanced Signal Processing on 16-bit MSP430 FRAM MCUs with Low Energy Accelerator (LEA)
This training series covers LEA or Low Energy Accelerator a vector math co-processor, the performance benchmark, and how to get started on the new MSP430FR599x. LEA is capable of performing various signal processing tasks efficiently without any CPU intervention. For example, LEA can perform a 256-point complex FFT in just ~5k cycles whereas a Cortex-M4F would take approximately 17k cycles (3.6x improvement).
Advanced Tuning Techniques for Capacitive Touch Sensing Applications with CapTIvate MCUs
Duration:
Anti-tamper Techniques to Thwart Attacks on Smart Meters
Non-technical losses (“theft”) account for billions of dollars of revenue loss for utility providers around the world as individuals are able to hack meters to slow or stop the accumulation of energy usage statistics. This loss has driven increased requirements for enhancing the protection designed into new smart meters. This training session will discuss different methods of attacking smart meters and how TI’s analog portfolio can be used to detect or even prevent these attacks. In one scenario magnets are used to saturate any transformers present in the system.
Anti-tamper Techniques to Thwart Attacks on Smart Meters— Detecting magnetic tampering using hall-effect sensors: Magnetic Tamper Detection Testing
Duration:
Anti-tamper Techniques to Thwart Attacks on Smart Meters— Detecting magnetic tampering using hall-effect sensors: TIDA-00839 Magnetic Tamper Detection Reference Design Features
Duration:
Anti-tamper Techniques to Thwart Attacks on Smart Meters— Hardening a meter against magnetic tamper attacks: Cap-Drop Based High-Side Power Supplies
Duration:
Anti-tamper Techniques to Thwart Attacks on Smart Meters— Hardening a meter against magnetic tamper attacks: Isolated Shunt Sensing Building Blocks
Duration:
Anti-tamper Techniques to Thwart Attacks on Smart Meters— Hardening a meter against magnetic tamper attacks: Transformer Based High-Side Power Supplies
Duration:
Anti-tamper Techniques to Thwart Attacks on Smart Meters— Summary
Duration:
Anti-tamper Techniques to Thwart Attacks on Smart Meters—Detecting case tamper attacks using inductive switches: Case Tamper Detection Implementations
Duration: