High Speed Signal Chain University is your portal to relevant training material on High Speed Data Converters and High Speed Amplifiers including topics related to RF Sampling Converters, JESD204B SerDes standard, and RF Fundamentals.
This video series provides information about the differences between the architectures of successive approximation register analog-to-digital converters (SAR ADCs) and delta-sigma ADCs. These videos are intended to help you know how to choose the best ADC architecture for your application.
This series provides lessons on some basic topics regarding precision digital-to-analog converters (DACs). The videos in this series cover a variety of topics including code-to-code glitch, calibration, common sources for error, and much more.
Engineer It is an educational, “how-to” video series where TI experts provide fundamental knowledge and solutions to overcome design challenges. Here, you can learn how to spin your motor in minutes, avoid amplifier input/output swing limitations, test and isolate power supplies and more from industry experts.
This three-part training series introduces fundamentals and tips for leveraging the JESD204B serial interface standard, which provides board area, FPGA/ASIC pin-count and deterministic latency improvements over traditional LVDS and CMOS interfaces. TI’s JESD204B ADCs, DACs, clock ICs and development tools enable quick evaluation, design and implementation of designs utilizing the JESD204B interface. Learn more today through this on-demand series.
Join our webinar series, as we explore different industry trends and technologies across our diverse product portfolio. Over the coming months, our experts will cover the latest analog, power management and embedded processing topics, across both automotive and industrial applications.
Were you unable to attend Tech Day but want to view the featured content? Did you attend and want to revisit a particular session? This series contains many of the sessions from the embedded processing, power supply design, signal chain, and wireless connectivity tracks. In addition, this series features recordings of select TI demos from the exhibitors hall.
These on-demand courses and tutorials include introductory ideas about device architecture in addition to advanced, application-specific problem-solving, using both theory and practical knowledge. Industry experts present each topic in order to help reduce design time and move quickly from proof-of-concept to productization. The ADC (analog-to-digital converter or A/D converter) curriculum is segmented into major topic learning categories, each of which contains short training videos, multiple choice quizzes, and short answer exercises.
High Accuracy AC Analog Input Module for Voltage & Current measurement using High Resolution Precision ADC for Protection Relay
Welcome to the world of power systems. This training session covers quick introduction to power systems and need for protection relay, protection relay modular architecture, AC analog input module (AIM), key specifications, time and frequency domain analysis, coherent, simultaneous and over sampling, selection of ADC and other key components and TI solutions. Design details for TI Design TIDA-00834 and links to TI designs customer can refer when designing AIM.
Delta-sigma analog-to-digital converters (ADCs) are oversampling converters typically used in applications requiring higher resolution. However, ADCs do not work by themselves. In fact, they require several key components around them, including a front-end amplifier, a voltage reference, a clock source, power supplies, and a good layout. Many devices integrate these features together with the ADC to offer a complete system solution, which simplifies the design for customers and minimizes board space.
Welcome to this training series: How to Measure ECG: A Guide to the Signals, System Blocks, and Solutions.
PT100/500/1000 Resistance Temperature Detectors (RTDs) are widely used in grid infrastructure and factory automation applications where high precision temperature measurement is often required. Technical requirements include either 20 mK precise Differential Temperature Measurement (DTM) for heat and cold meters from 0 to 180°C or better than 400 mK precision over the full range of -200 to 850°C for industrial sensor transmitters.
The HART of the Current Loop: Designing SMART Field Transmitters and PLCs with TI's Very First HART Modem
The report illustrates a differentially driven signal fed into TI’s 20 bit SAR ADC. This results in raw data available for data processing. This has zero latency and high linearity.
This TI design illustrate the CW Doppler signal conditioning for an ultrasound machine. The input signal bandwidth up to 100KHz and 128 differential signals from AFEs are summed together in a differential high speed amplifier and digitized with TI SAR ADC.
This presentation also addresses :
An adaptive circuit for adjusting the cut off frequency of anti-aliasing circuit in our explanations.
The Precision DAC Learning Center is a collection of technical content that will help guide you through the precision DAC design process. Whether you are learning the basics of digital-to-analog conversion or trying to understand how to implement a precision DAC in your system, this learning center provides a range of videos, articles, and blogs to help you along the way.
The topics will cover system design issue and solution for Building Automation, Power Delivery and Test & Measurement. TI experts introduce the latest technology and innovation system reference design. Discover ways to enhance the time-to-market and create safer and efficient industrial systems.
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.