SLUAAL2 june   2023 UCC256402 , UCC256403 , UCC256404

 

  1.   1
  2.   Abstract
  3.   Trademarks
  4. 1UCC25640x Frequently Asked Questions
    1. 1.1  For the Time Domain Simulation and Fundamental Harmonic Analysis of LLC Resonant Converters, What Model of the Transformer Should be Used?
      1. 1.1.1 LLC Design Using T Type Transformer Model
    2. 1.2  How to Connect External Gate Drivers to the UCC25640x for High Gate Driver Current Capability?
    3. 1.3  When Powering on the PFC-LLC AC-DC Converter, What Sequence is Recommended?
    4. 1.4  How to Eliminate the Nuisance ZCS Detection During the Light Load?
    5. 1.5  What is the Purpose of Maintaining the FB Pin Voltage of the UCC25640x Controllers at a Constant Level?
    6. 1.6  How to Improve the Slew Rate Detection at HS Pin of the UCC25640x Controller?
    7. 1.7  How to Operate the UCC25640x Controller in the Open Loop?
    8. 1.8  What Happens if the VCR Pin Peak to Peak Voltage of the Controller Exceeds 6 V?
    9. 1.9  What UCC25640x settings effect the startup duration of the LLC?
    10. 1.10 What is Causing the Current Imbalance in the LLC's Secondary Side Windings?
    11. 1.11 How to Design TL431 Compensator for LLC With UCC25640x Controller
      1. 1.11.1 LLC Plant Transfer Function Under HHC Control
      2. 1.11.2 Type 2 and Type 3 Compensator with TL431 [20]
        1. 1.11.2.1 Type 2 Compensator
        2. 1.11.2.2 Type 2 Compensator Without Fast Lane
        3. 1.11.2.3 Type 3 Compensator with Fast Lane
        4. 1.11.2.4 Type 3 Compensator Without Fast Lane
      3. 1.11.3 Type 3 Compensator Design Example
    12. 1.12 How to Design LLC for Battery Charging and LED Driver Applications?
      1. 1.12.1 LED Driver Design Example
      2. 1.12.2 Battery Charger Design Example
    13. 1.13 How to Implement CC-CV Feedback Control?
      1. 1.13.1 Voltage Feedback Loop (Type 2) Transfer Function
      2. 1.13.2 Current Feedback Loop (Type 2) Transfer Function
    14. 1.14 What is the Simplest Approach to Configure the Burst Mode Thresholds for UCC25640x Based on the Load Power?
    15. 1.15 How to Avoid the UCC25640x Controller to Enter into Burst Mode?
    16. 1.16 What are the Methods for Preventing VCC From Decreasing Below the VCC Restart Threshold During Burst Mode?
    17. 1.17 How Does BMTL Threshold Value Impacts the Output Voltage Ripple and the VCC Pin Voltage and Magnetizing Current?
    18. 1.18 How to Design Magnetics for LLC?
      1. 1.18.1 LLC Resonant Inductor Design
      2. 1.18.2 LLC Transformer Design
    19. 1.19 How is the Dead Time in UCC25640x Determined During ZCS Detection and in the Absence of Valid Slew Rate Detection?
  5. 2References

1.19 How is the Dead Time in UCC25640x Determined During ZCS Detection and in the Absence of Valid Slew Rate Detection?

Case 1: Valid Slew Rate Detection and No ZCS

As soon as the high side gate (HO) is turned off, the low side gate (LO) will be turned on after the slew rate has been detected. The same dead time will be copied over during low side turn off to high side turn on.

Case 2: No Slew Rate Detection and No ZCS

If no valid slew rate detection occurs after the HO turn off, the dead time during both transitions (HO turn off to LO turn on) and (LO turn off to HO turn on) depends on the resonant current polarity. Furthermore, this dead time will not exceed 1.1us.

Case 3: ZCS during HO turn off and No ZCS during LO turn off

If the ZCS is detected during HO turn off, the dead time from HO off to LO on is determined by the following factors:

  1. The slew rate detection .
  2. If no appropriate slew rate detection is available, it is determined by the polarity of the resonant current (ISNS signal). The maximum dead time here will not exceed 150us.

The dead time during LO turn off to HO turn on depends on the resonant current polarity. Furthermore, this dead time will not exceed 1.1us.

Case 4: No ZCS during HO turn off and ZCS during LO turn off

The dead time during HO off to LO on depends on the slew rate detection similar to case1. However, If no valid slew rate detection occurs after the HO turn off, the dead time during HO turn off to LO turn on depends on the resonant current polarity. Furthermore, this dead time will not exceed 1.1us.

If the ZCS is detected during LO turn off, the dead time from LO off to HO on is determined by the polarity of the resonant current (ISNS signal). The maximum dead time here will not exceed 150 us.

Case 5: ZCS during both HO turn off and LO turn off

If the ZCS is detected during HO turn off, the dead time from HO off to LO on is determined by the following factors:

  1. The slew rate detection
  2. If no appropriate slew rate detection is available, it is determined by the polarity of the resonant current (ISNS signal). The maximum dead time here will not exceed 150 us.

If the ZCS is detected during LO turn off, the dead time from LO off to HO on is determined by the polarity of the resonant current (ISNS signal). The maximum dead time here will not exceed 150 us.