ZHCSKK3B December 2019 – February 2022 TPS6594-Q1
PRODUCTION DATA
The high frequency and large switching currents of the TPS6594-Q1 device make the choice of layout important. Good power supply results only occur when care is given to correct design and layout. Layout affects noise pickup and generation and can cause a good design to perform with less-than-expected results.
With a range of buck output currents from a few milliampere to 10 A and over, good power supply layout is much more difficult than most general PCB design. Use the following steps as a reference to ensure the buck regulators are stable and maintain correct voltage and current regulation across its intended operating voltage and current range.
For the LDO regulators, the feedback connection is internal. Therefore, it is important to keep the PCB resistance between LDO output and target load in the range of the acceptable voltage drop for LDOs. Similar to the buck regulators, the input capacitor at the PVIN_LDOx pins and the VCCA pin must be placed as close as possible to the PMIC. The impedance from the source of the PVIN_LDOx pins and the VCCA pin must be low and the DCR less than 2 mΩ. The output capacitor at the VOUT_LDOx, VOUT_LDOVINT and VOUT_LDOVRTC pins must be as close (0.5mm) to the PMIC as possible. The ground connection of these capacitors, especially for the capacitor at the VOUT_LDOVINT pin, must have a low impedance of less than 2 mΩ to the ground (Thermal Pad) of the TPS6594-Q1. For the ground connection of this capacitor at the VOUT_LDOVINT pin, use multiple vias (at least three) directly at the ground landing pad of the capacitor. See illustration below:
Due to the overall small solution size, the thermal performance of the PCB layout is important. Many system-dependent parameters, such as thermal coupling, airflow, added heat sinks and convection surfaces, and the presence of other heat-generating components affect the power dissipation limits of a given component. Proper PCB layout, focusing on thermal performance, results in lower die temperatures. Wide and thick power traces come with the ability to sink dissipated heat. The capability to sink dissipated heat can be improved further on multi-layer PCB designs with vias to different planes. Improved heat-sinking capability results in reduced junction-to-ambient (RθJA) and junction-to-board (RθJB) thermal resistances and thereby reduces the device junction temperature, TJ. TI strongly recommends to perform a careful system-level 2D or full 3D dynamic thermal analysis at the beginning product design process, by using a thermal modeling analysis software.
Overall recommendation for the PCB is to use at least 12 layers with 60 to 90 mil thickness, and with following weights for the Copper layers:
A more complete list of layout recommendations can be found in the Schematic and layout checklist.