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An Engineer's Guide to Isolated Signal Chain Solutions
- SLYY234 December 2024 AMC0106M05 , AMC0106M25 , AMC0136 , AMC0311D , AMC0311S , AMC0386 , AMC0386-Q1 , AMC1100 , AMC1106M05 , AMC1200 , AMC1200-Q1 , AMC1202 , AMC1203 , AMC1204 , AMC1211-Q1 , AMC1300 , AMC1300B-Q1 , AMC1301 , AMC1301-Q1 , AMC1302-Q1 , AMC1303M2510 , AMC1304L25 , AMC1304M25 , AMC1305M25 , AMC1305M25-Q1 , AMC1306M05 , AMC1306M25 , AMC1311 , AMC1311-Q1 , AMC131M03 , AMC1336 , AMC1336-Q1 , AMC1350 , AMC1350-Q1 , AMC23C12 , AMC3301 , AMC3330 , AMC3330-Q1

CONTENTS
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An Engineer's Guide to Isolated Signal Chain Solutions

1
Introduction
Introduction to Isolated Signal Chain
1. Comparing Isolated Amplifiers and Isolated Modulators
  1. Abstract
  2. Introduction to Isolated Amplifiers
  3. Introduction to Isolated Modulators
  4. Performance Comparison Between Isolated Amplifiers and Isolated Modulators
  5. Isolated Modulators in Traction Inverters
  6. Isolated Amplifier and Modulator Recommendations
  7. Conclusion
2. TI’s First Isolated Amplifiers With Ultra-Wide Creepage and Clearance
  1. Application Brief
Selection Trees
Current Sensing
1. Shunt Resistor Selection for Isolated Data Converters
  1. 17
2. Design considerations for isolated current sensing
  1. 19
  2. Conclusion
  3. References
  4. Related Websites
3. Isolated Current-Sensing Circuit With ±50-mV Input and Single-Ended Output
  1. 24
4. Isolated Current-Sensing Circuit With ±50-mV Input and Differential Output
  1. 26
5. Isolated Current-Sensing Circuit With ±250-mV Input Range and Single-Ended Output Voltage
  1. Design Goals
  2. Design Description
  3. Design Notes
  4. Design Steps
  5. Design Simulations
  6. DC Simulation Results
  7. Closed-Loop AC Simulation Results
  8. Transient Simulation Results
  9. Design References
  10. Design Featured Isolated Amplifier
  11. Design Alternate Isolated Amplifier
6. Isolated current-measurement circuit with ±250-mV input and differential output
  1. Design Goals
  2. Design Description
  3. Design Notes
  4. Design Steps
  5. Design Simulations
  6. DC Simulation Results
  7. Closed Loop AC Simulation Results
  8. Transient Simulation Results
  9. Design References
  10. Design Featured Op Amp
  11. Design Alternate Op Amp
7. Isolated Overcurrent Protection Circuit
  1. 52
8. Interfacing a Differential-Output (Isolated) Amp to a Single-Ended Input ADC
  1. 54
9. Utilizing AMC3311 to Power AMC23C11 for Isolated Sensing and Fault Detection
  1. Application Brief
10. Isolated Current-Sensing Circuit With Front-End Gain Stage
  1. 58
11. Accuracy Comparison of Isolated Shunt and Closed-Loop Current Sensing
  1. 60
Voltage Sensing
1. Maximizing Power Conversion and Motor Control Efficiency With Isolated Voltage Sensing
  1. 63
  2. Solutions for high-voltage sensing
  3. Integrated resistor devices
  4. Single-ended output devices
  5. Integrated isolated voltage-sensing use cases
  6. Conclusion
  7. Additional resources
2. Increased Accuracy and Performance with Integrated High Voltage Resistor Isolated Amplifiers and Modulators
  1. Abstract
  2. Introduction
  3. High Voltage Resistor Isolated Amplifiers and Modulators Advantages
    1. Space Savings
    2. Improved Temperature and Lifetime Drift of Integrated HV Resistors
    3. Accuracy Results
    4. Fully Integrated Resistors vs. Additional External Resistor Example
    5. Device Selection Tree and AC/DC Common Use Cases
  4. Summary
  5. References
3. Isolated Amplifiers With Differential, Single-Ended Fixed Gain and Ratiometric Outputs for Voltage Sensing Applications
  1. Abstract
  2. Introduction
  3. Overview of Differential, Single-Ended Fixed Gain and Ratiometric Outputs
  4. Application Examples
    1. Product Selection Tree
  5. Summary
  6. References
4. Isolated Voltage-Measurement Circuit With ±250-mV Input and Differential Output
  1. 93
5. Split-Tap Connection for Line-to-Line Isolated Voltage Measurement Using AMC3330
  1. 95
6. ±12V Voltage Sensing Circuit With an Isolated Amplifier and Pseudo-Differential Input SAR ADC
  1. 97
7. ±12-V voltage sensing circuit with an isolated amplifier and differential input SAR ADC
  1. 99
8. Isolated Undervoltage and Overvoltage Detection Circuit
  1. 101
9. Isolated Zero-Cross Detection Circuit
  1. 103
10. ±480V Isolated Voltage-Sensing Circuit With Differential Output
  1. 105
EMI Performance
1. Best in Class Radiated Emissions EMI Performance with Isolated Amplifiers
2. Best Practices to Attenuate AMC3301 Family Radiated Emissions EMI
  1. Abstract
  2. Introduction
  3. Effects of Input Connections on AMC3301 Family Radiated Emissions
  4. Attenuating AMC3301 Family Radiated Emissions
    1. Ferrite Beads and Common Mode Chokes
    2. PCB Schematics and Layout Best Practices for AMC3301 Family
  5. Using Multiple AMC3301 Devices
    1. Device Orientation
    2. PCB Layout Best Practices for Multiple AMC3301
  6. Conclusion
  7. AMC3301 Family Table
End Equipment
1. Comparing Shunt- and Hall-Based Isolated Current-Sensing Solutions in HEV/EV
  1. 128
2. Design Considerations for Current Sensing in DC EV Charging Applications
  1. Abstract
  2. Introduction
    1. DC Charging Station for Electric Vehicles
    2. Current-Sensing Technology Selection and Equivalent Model
      1. Sensing of the Current With Shunt-Based Solution
      2. Equivalent Model of the Sensing Technology
  3. Current Sensing in AC/DC Converters
    1. Basic Hardware and Control Description of AC/DC
      1. AC Current Control Loops
      2. DC Voltage Control Loop
    2. Point A and B – AC/DC AC Phase-Current Sensing
      1.        Impact of Bandwidth
        
                Steady State Analysis: Fundamental and Zero Crossing Currents
        
                Transient Analysis: Step Power and Voltage Sag Response
      2. Impact of Latency
        
        Fault Analysis: Grid Short-Circuit
      3.        Impact of Gain Error
        
                Power Disturbance in AC/DC Caused by Gain Error
        
                AC/DC Response to Power Disturbance Caused by Gain Error
      4. Impact of Offset
    3. Point C and D – AC/DC DC Link Current Sensing
      1. Impact of Bandwidth on Feedforward Performance
      2. Impact of Latency on Power Switch Protection
      3. Impact of Gain Error on Power Measurement
        
        Transient Analysis: Feedforward in Point D
      4. Impact of Offset
    4. Summary of Positives and Negatives at Point A, B, C1/2 and D1/2 and Product Suggestions
  4. Current Sensing in DC/DC Converters
    1. Basic Operation Principle of Isolated DC/DC Converter With Phase-Shift Control
    2. Point E, F - DC/DC Current Sensing
      1. Impact of Bandwidth
      2. Impact of Gain Error
      3. Impact of Offset Error
    3. Point G - DC/DC Tank Current Sensing
    4. Summary of Sensing Points E, F, and G and Product Suggestions
  5. Conclusion
  6. References
3. Using isolated comparators for fault detection in electric motor drives
4. Discrete DESAT for Opto-Compatible Isolated Gate Driver UCC23513 in Motor Drives
  1. Abstract
  2. Introduction
  3. System Challenge on Isolated Gate Drivers With Integrated DESAT
  4. System Approach With UCC23513 and AMC23C11
    1. System Overview and Key Specification
    2. Schematic Design
      1. Circuit Schematic
      2. Configure VCE(DESAT) Threshold and DESAT Bias Current
      3. DESAT Blanking Time
      4. DESAT Deglitch Filter
    3. Reference PCB Layout
  5. Simulation and Test Results
    1. Simulation Circuit and Results
      1. Simulation Circuit
      2. Simulation Results
    2. Test Results With 3-Phase IGBT Inverter
      1. Brake IGBT Test
      2. Test Results on a 3-Phase Inverter With Phase to Phase Short
  6. Summary
  7. References
5. Isolated voltage sensing in AC motor drives
  1. Introduction
  2. Conclusion
  3. References
6. Achieving High-Performance Isolated Current and Voltage Sensing in Server PSUs
  1. Application Brief
Additional Reference Designs/Circuits
1. Designing a Bootstrap Charge-Pump Power Supply for an Isolated Amplifier
  1. Abstract
  2. Introduction
  3. Bootstrap Power Supply Design
    1. Selection of Charge Pump Capacitor
    2. Simulation in TINA-TI
    3. Hardware Test with AMC1311-Q1
  4. Summary
  5. Reference
2. Clock Edge Delay Compensation With Isolated Modulators Digital Interface to MCUs
  1. Abstract
  2. Introduction
  3. Design Challenge With Digital Interface Timing Specifications
  4. Design Approach With Clock Edge Delay Compensation
  5. Test and Validation
    1. Test Equipment and Software
    2. Testing of Clock Signal Compensation With Software Configurable Phase Delay
      1. Test Setup
      2. Test Measurement Results
    3. Testing of Clock Signal Compensation by Clock Inversion at MCU
      1. Test Setup
      2.        Test Measurement Results
        
                Test Result – No Clock Inversion of Clock Input at GPIO123
        
                Test Result – Clock Inversion of Clock Input at GPIO123
    4. Digital Interface Timing Validation by Calculation Tool
  6. Conclusion
  7. References
3. Utilizing AMC3311 to Power AMC23C11 for Isolated Sensing and Fault Detection
  1. Application Brief
IMPORTANT NOTICE

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E-Book

An Engineer's Guide to Isolated Signal Chain Solutions

Introduction

Designers have many options when addressing the challenges associated with designing an accurate isolated current and voltage measurement circuit. Approaches range from using from discrete implementations, through isolated amplifiers and modulators, to magnetic sensing technologies. Technology of choose varies based on the system, regulations, and flexibility a designer has for their of current sensing or voltage sensing applications – the different types of technologies allows the designer to specifically address their unique design challenges.

This e-book was created to further simplify the current and voltage sensing design process by helping you quickly and efficiently narrow down the list of potential devices that align best with your particular system’s requirements.

The current and voltage sensing information featured in this e-book address specific current sensing and voltage sensing use-cases, applications, focusing on identifying the most optimized device to best serve the challenges faced in that particular application and offer alternative solutions that may be beneficial for other circuit optimizations.

Although this e-book is not an exhaustive collection of current and voltage-sensing challenges, it does address many of the more common and challenging functional circuits seen today. If you have any questions about the topics covered here or any other current and voltage sensing questions, submit them to the TI E2E™ design support forums Amplifiers forum.

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