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TI Precision Labs - Op Amps

TI Precision Labs is the electronics industry’s most comprehensive online classroom for analog engineers. The 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. Use these hands-on courses to predict circuit performance and move seamlessly from abstract concepts to specific formulae in an easy-to-follow format. Industry experts present each topic in order to help reduce design time and move quickly from proof-of-concept to productization.

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.

Modern Op Amps in Old School Designs

TI’s op amp specs are generally better than or equal to nearly all of the legacy part specs.  Whether your focus is on personal electronics, industrial or medical, every engineer interested in learning how to combat the problem of why our higher performance, lower cost op amps sometimes don’t work in legacy sockets should view this training. Learn from a training structured “definition by example”, based on real world cases to de-mystify these “TI doesn’t work in my legacy socket” occurrences.

South Asia Industrial Webinar

2018 South Asia Industrial Webinar Series

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.

Troubleshooting amplifier amplifiers integrated circuit PCB printed circuit board application linear AMP offset output voltage datasheet verification failure analysis debugging debug

Troubleshooting Tips: Op Amps

The linear amplifier troubleshooting guide highlights various techniques to assist with application problem-solving, debugging and datasheet measurements on TI specific products. The hands-on courses aid in circuit analysis, isolate the root cause of an application non-conformance and provide detailed product level information to a TI representative. Industry experts present each topic in order to help reduce debugging time and move quickly through troubleshooting to production.

op amps

TI Precision Labs - Op Amps: Introduction

What is this training series about? Is it right for me?

These introduction videos give the background on the TI Precision Labs and explain their broad appeal to engineers of all experience levels. The second video introduces the National Instruments VirtualBench which is recommended for use in the hands-on labs accompanying the training modules.

input offset and bias current

TI Precision Labs - Op Amps: Input Offset Voltage and Input Bias Current

How well do you know the major contributors to DC op amp input errors?

op amps training

TI Precision Labs - Op Amps: Input and Output Limitations

Have you ever experienced unexpected signal output behavior of an op amp, such as clipping or other non-linear behavior?

The cause of this may be either input common mode voltage limitations or output voltage swing restrictions.  Understanding data sheet specifications in the context of real world circuits will help you avoid experiencing this problem.  An inside look at an op amp's input and output stages on different process technologies provides additional insight.

power and limitations

TI Precision Labs - Op Amps: Power and Temperature

How hot is too hot? Does my circuit need a heat sink?

This series discusses the relationship between power dissipation and temperature in op amps and shows how to calculate an amplifier's junction temperature under a variety of operating conditions using its thermal model. Absolute maximum ratings and internal thermal protection schemes are also introduced.

op amp bandwidth

TI Precision Labs - Op Amps: Bandwidth

Did you know when calculating op amp bandwith you should always use the non-inverting gain?  Do you know why bandwidth impacts Iq?

In addition to answering those questions, we will show you nearly everything you ever wanted to know about op amp bandwidth including:

TI Precision Labs - Op Amps: Slew Rate

True or False? A large and rapid voltage change in an op amp's output is always limited by the slew rate of the device.

If you think the answer is true, or you have seen output slew behavior you could not explain, this session is for you!  We will provide an explanation of large and small signal analysis, slew boost, slew rate over temperature, slew rate vs. full power bandwidth, and the relationship of Vos and slew rate.  In addition, an inside the op amp view of the cause of slew rate limit is presented.

TI Precision Labs - Op Amps: Common Mode Rejection and Power Supply Rejection

Rejection can be a good thing, especially in the case of common mode or power supply voltage errors. 

This video series discusses how changing the common mode voltage or power supply voltage on an op amp can introduce errors at both AC and DC, and how those errors are mitigated by the op amp's built-in common mode rejection and power supply rejection.

TI Precision Labs - Op Amps: Noise

Did you know that a standard resistor component sitting upon your desk doing "nothing" is actually generating noise?

TI Precision Labs - Op Amps: Low Distortion Design

Distortion - a linear circuit's worst enemy. Where does it come from and how can it be reduced?

This video series introduces the sources of distortion in amplifier circuits, both internal to the amplifier and from external components. Design practices which minimize distortion are also given.

TI Precision Labs - Op Amps: Stability

Did the circuit you designed to create a precision DC output end up as an oscillator?

After viewing this series, you should have all of the tools and information to prevent this from happening again!  This session covers basic stability theory, applies it to SPICE  simulations, and then real-world lab experiments.  You will learn the common causes of op amp stability issues as well as common stability compensation techniques and their associated tradeoffs.

TI Precision Labs - Op Amps: ESD

ZAP! Is your circuit protected against the thousands of volts which could be on your finger tips?

This series explains how electrostatic discharge, or ESD, can damage semiconductor components and what kind of internal protection circuitry is present in these devices.

TI Precision Labs - Op Amps: Electrical Overstress (EOS)

Oops, what's that smell:  why did the "smoke test" fail?

This series covers the causes of electrical overstress and introduces several methods that can be used to improve and test circuit robustness against electrical overstress.  All of the examples in this series show op-amp circuits, but the methods used could be applied to other components as well.

TI Precision Labs - Op Amps: Board Level Troubleshooting

My application circuit doesn't work! What should I do now?

This video series gives recommendations for best practice application debugging techniques. Various engineering checks are outlined to help determine the root cause of an issue.

For more detailed amplifier troubleshooting videos, check out the Linear Amplifier Troubleshooting Training Series.

TI Precision Labs - Op Amps: Current-Feedback Amplifiers

What is a current-feedback amplifier, and when is it the best choice for your system design?

In this series, you will learn the main advantages of current-feedback amplifiers, namely:

TI Precision Labs - Op Amps: Fully Differential Amplifiers

How would you convert a single-ended signal from a sensor to a fully differential signal in order to drive an ADC?

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