These videos describe the different types front-end topologies that can be used to drive the input signal of an ADC.
These videos describe how to calculate the error and noise of analog-to-digital converters (ADCs).
These videos describe how to analyze analog-to-digital converter (ADC) performance specifications that are measured using AC input signals.
These videos describe how to design the input driver circuitry for a SAR ADC.
This section covers SAR voltage reference specifications, reference behavior and methods for driving the reference input that minimizes error.
These videos describe how to design a low-power data acquisition system using a successive approximation register (SAR) analog-to-digital converter (ADC).
These videos cover the fundamentals of high-speed data converters, including an overview of the architectures of both ADCs and DACs.
The first part of the session focuses on an introduction to power systems and goals of power system protection.
This session explains the use case for protection relay, the sequence of events during a fault, fault types and the approach for fault analysis.
This session explains the representation of voltage or current waveforms in the time and frequency domain.
Design details for TIDA-00834 high accuracy analog front-end using 16-bit SAR ADC with ±10V measurement range reference design
The fifth-part of the session will focus on providing detailed information on the TIDA-00834 design.
This section introduces the heat and cold meter training series.
ADS1220 delta-sigma family uses the ratiometric approach for measuring RTD sensors with the built-in current excitation source.
TIDA-01526 implements a high-precision DTM sub-system using a 24-bit, low-power, Delta-Sigma ADC.
The TMP116 digital precision temperature sensor for the -55 to +125ºC range achieves higher accuracy than the Class AA PT sensor with a 1-point calibration.
Take a look at common precision DAC architectures, and find the perfect fit for your design.