SLVAF66 June   2021 DRV3255-Q1 , DRV8300 , DRV8301 , DRV8302 , DRV8303 , DRV8304 , DRV8305 , DRV8305-Q1 , DRV8306 , DRV8307 , DRV8308 , DRV8320 , DRV8320R , DRV8323 , DRV8323R , DRV8340-Q1 , DRV8343-Q1 , DRV8350 , DRV8350F , DRV8350R , DRV8353 , DRV8353F , DRV8353R

 

  1. Introduction to High-Power Motor Applications
    1. 1.1 Effects of a Poorly-Designed High-Power Motor Driver System
    2. 1.2 Example of the High-Power Design Process
  2. Examining a High-Power Motor Drive System at a High Level
    1. 2.1 Anatomy of the Motor Drive Power Stage and How to Troubleshoot
    2. 2.2 Troubleshooting a High-Power System
  3. High-Power Design Through MOSFETs and MOSFET Gate Current (IDRIVE)
    1. 3.1 MOSFET Gate Current
      1. 3.1.1 How Gate Current Causes Damage
      2. 3.1.2 Gate Resistors and Smart Gate Drive Technology
        1. 3.1.2.1 Gate Resistors
        2. 3.1.2.2 Smart Gate Drive and Internally-Controlled Sink and Source Gate Currents
        3. 3.1.2.3 Summary for Gate Resistors and Smart Gate Drive Technology
      3. 3.1.3 Example Gate Current Calculation for a Given FET
  4. High-Power Design Through External Components
    1. 4.1 Bulk and Decoupling Capacitors
      1. 4.1.1 Note on Capacitor Voltage Ratings
    2. 4.2 RC Snubber Circuits
    3. 4.3 High-Side Drain to Low-Side Source Capacitor
    4. 4.4 Gate-to-GND Diodes
  5. High-Power Design Through a Parallel MOSFET Power Stage
  6. High-Power Design Through Protection
    1. 6.1 VDS and VGS Monitoring
      1. 6.1.1 Turning Off the FETs During an Overcurrent, Shoot-Through, or FET Shorting Event
    2. 6.2 Passive Gate-to-Source Pulldown Resistors
    3. 6.3 Power Supply Reverse Polarity or Power Supply Cutoff Protection
  7. High-Power Design Through Motor Control Methods
    1. 7.1 Brake versus Coast
      1. 7.1.1 Algorithm-Based Solutions
      2. 7.1.2 External Circuit Solutions
      3. 7.1.3 Summary of Brake versus Coast
  8. High-Power Design Through Layout
    1. 8.1 What is a Kelvin Connection?
    2. 8.2 General Layout Advice
  9. Conclusion
  10. 10Acknowledgments

3.1.2.1 Gate Resistors

Figure 3-2 Sink and Source Resistors When Gate Current is Fixed

In most gate driver devices, the source and sink, or pullup and pulldown, gate-drive current values are found in the data sheet. In some devices, this value is fixed internally, and the output current capability is much larger than the calculated IDRIVE for a given FET.

Add an external series gate resistor to control the slew rate of the applied gate voltage and reduce the peak current applied to the gate of the FET. This is similar to a RC filter: R is the gate resistor, and C is the inherent capacitance of the MOSFET. For further control, place another gate resistor and diode in parallel – if the designer wants to control sink and source separately. This is shown in Figure 3-2.

The MOSFET parameters, system voltage, and board parasitics all affect the final slew rate, so selecting an optimal gate resistor value is an iterative process. This process is explained in the External Gate Resistor Design Guide for Gate Drivers tech note.

There is a helpful principle that is beneficial to help determine the best resistance to use for a gate resistor: less resistance equals more current with a faster slew rate, and more resistance equals less current with a slower slew rate.