SLUAAJ1 May   2022 TPS62860 , TPS62861 , TPS62864 , TPS62866 , TPS62868 , TPS62869 , TPS62870 , TPS62870-Q1 , TPS62871 , TPS62871-Q1 , TPS62872 , TPS62872-Q1 , TPS62873 , TPS62873-Q1 , TPS62874-Q1 , TPS62875-Q1 , TPS62876-Q1 , TPS62877-Q1 , TPSM82810 , TPSM82813 , TPSM82816 , TPSM82864A , TPSM82866A , TPSM8287A06 , TPSM8287A12 , TPSM8287A15

 

  1.   Trademarks
  2. 1Understanding Different Thermal Metrics
  3. 2Understanding SOA Curves
  4. 3How to Create the SOA Curve
  5. 4Designing for Optimal Thermal Performance
  6. 5Summary

4 Designing for Optimal Thermal Performance

The RθJA value is one metric to quantify a device’s thermal performance. The RθJA value depends on the power module’s design, as well as the PCB’s design. Having external thermal pads under the package allows good thermal performance by allowing multiple GND vias to heat sink the device to the PCB’s multiple GND layers. Also, having a pin-out that allows large copper planes to connect to the device’s power pins (VIN, GND, VOUT) reduces the RθJA value. Figure 4-1 shows that the TPSM82866A provides a large thermal pad, while Figure 4-2 shows that the pin-out allows an easy plane connection to the power pins.

Figure 4-1 TPSM82866A Package with Exposed Thermal Pad
Figure 4-2 TPSM82866A Layout Example

Once the power module is designed for good thermal performance, the PCB must be designed to work effectively with the power module to remove the power loss. Thermal vias should be placed beneath the thermal pad to transfer the heat from the power module to the layers within the PCB. Placing multiple vias closely spaced to each other reduces the RθJA value. However, once a few vias are placed on the thermal pad, the point of diminishing returns is reached and adding more vias does not usually reduce the value significantly. The number of vias shown in the data sheet’s layout example or in the package drawing is a good starting point for achieving good thermal performance. Thermal Performance Optimization of High-Power Density Buck Converters discusses the impact of vias on thermal performance in detail.

In addition to thermal vias, having ground planes on multiple PCB layers and increasing the copper area connected to the power pins of the device helps improve the thermal performance. Adding airflow greatly reduces the RθJA value. Improving the Thermal Performance of a MicroSiP™ Power Module provides more details on improving thermal performance through thermal vias and additional PCB layers.