Based on the LM5137F-Q1-EVM5D3 design, Figure 8-26 shows a single-sided layout of a dual-output synchronous buck regulator. The design uses layer 2 of the PCB as a power-loop ground return path directly underneath the top layer to create a low-area switching power loop of approximately 2mm². This loop area, and hence parasitic inductance, must be as small as possible to minimize switch-node voltage overshoot and ringing (and hence the overall EMI signature). Refer to the LM25137F-Q1-EVM5D3 Evaluation Module EVM user's guide for more detail.

Figure 8-26 PCB Top Layer

As shown in Figure 8-27, the high-frequency power loop current flows through MOSFETs Q3 and Q4, through the power ground plane on layer 2, and back to VIN through the 0603 ceramic capacitors C30 through C33. The currents flowing in opposing directions in the vertical loop configuration provide field self-cancellation, reducing parasitic loop inductance. Figure 8-28 shows a side view to illustrate the concept of creating a low-profile, self-canceling loop in a multilayer PCB structure. The layer-2 GND plane layer, shown in Figure 8-27, provides a tightly-coupled current return path directly under the MOSFETs to the source terminals of Q4.

Four 10nF input capacitors with small 0603 case size, place in parallel close to the drain of each high-side MOSFET. The low ESL and high self-resonant frequency (SRF) of the small footprint capacitors yield excellent high-frequency performance. The negative terminals of these capacitors connect to the layer-2 GND plane with multiple 12mil (0.3mm) diameter vias, further reducing parasitic inductance.

Additional steps used in this layout example include:

• Keep the SW connection from the power MOSFETs to the inductor (for each channel) at minimum copper area to reduce capacitive coupling and radiated EMI.
• Locate the IC close to the gate terminals of the MOSFETs and route the gate drive traces short and direct.
• Create an analog ground plane near the IC for sensitive analog components. Connect the AGND plane and the PGND power ground planes at a single point at the die attach pad (DAP) of the IC.

Figure 8-27 Power Stage Component Layout

Note: See the Improve High-current DC/DC Regulator Performance for Free with Optimized Power Stage Layout application brief for more detail.

Figure 8-28 PCB Stack-Up Diagram With Low L1-L2 Intra-layer Spacing