STDA015 February   2026 DRV8163-Q1 , DRV8263-Q1 , LM61495-Q1 , LM70880-Q1 , LM74500-Q1 , LMR36503-Q1 , MCF8329A-Q1 , TLIN4029A-Q1

 

  1.   1
  2.   Abstract
  3.   Trademarks
  4. 1Introduction
  5. 2Examples of Using 48V in Body Motor Applications
    1. 2.1 Door Module
    2. 2.2 Window Lift
    3. 2.3 Wiper
    4. 2.4 Power Seat
  6. 3Benefits of 48V Supply
    1. 3.1 Increased Integration of Half-Bridges with 48V
    2. 3.2 Size Comparison Between 48V Integrated Driver vs 12V Gate Driver
    3. 3.3 Example Placement Study
  7. 4Thermal and EMC Performance Trade-off Considerations
    1. 4.1 Conduction Losses in the MOSFETs
    2. 4.2 Switching Losses During PWM
    3. 4.3 Experimental Results Show Effect of Slew Rate on Transistor Temperature During PWM
    4. 4.4 Fast Slew Rates Impact Electromagnetic Emissions
  8. 5Summary
  9. 6About the Authors
  10. 7References

5 Summary

In summary, the transition to 48V systems in automotive applications presents both opportunities and challenges for body motor applications. While increased integration of half-bridges offers benefits in terms of size and complexity, thermal management and EMC performance need careful consideration, especially for applications such as window lifts and power seats. The choice between integrated and gate driver designs depends on specific design priorities and application requirements.

The shift to 48V systems for automotive body motors demands a holistic approach that considers both thermal and EMC aspects throughout the design and development process. Careful selection of components, optimized thermal management strategies, and robust EMC design techniques are essential to reap the benefits of 48V systems while verifying the reliability, safety, and functionality of the overall automotive electrical system.