Proper PCB design and layout is important in
high-current, fast-switching converter circuits (with high current and voltage slew rates)
to achieve reliable device operation and design robustness. Furthermore, the EMI performance
of the converter depends to a large extent on PCB layout.
The high-frequency power loop of a buck
regulator power stage is denoted in red and the topological architecture of a buck regulator
means that particularly high di/dt current flows in the components shown in Figure 7-36. Reducing the parasitic
inductance of this loop by minimizing the effective loop area becomes mandatory.
The following list summarizes the essential
guidelines for PCB layout and component placement to optimize DC/DC converter performance,
including thermals and EMI signature. Figure 7-37 shows a recommended layout of the LM706A0-Q1 with optimized
placement and routing of the power-stage and small-signal components.
- Place the input capacitors as close as
possible to the input power pins: The VIN and PGND pins are close together (with a
gap in between to increase clearance), thus simplifying input capacitor placement.
- Use low-ESR ceramic capacitors with
X7R or X7S dielectric from VIN to PGND. Place an 0402 capacitor close to VIN for
high-frequency bypass as shown in Figure 7-37. Use additional 1206 or 1210 capacitors for bulk capacitance.
- Ground return paths for both the
input and output capacitors must consist of localized top-side planes that connect to
the PGND pins.
- Use a solid ground plane on the PCB
layer beneath the top layer with the IC: This plane acts as a noise shield and a
heat dissipation path. Using the PCB layer directly below the IC minimizes the magnetic
field associated with the currents in the switching loops, thus reducing parasitic
inductance and switch voltage overshoot and ringing. Use numerous thermal vias near PGND
for heatsinking to the inner ground planes.
- Make the VIN, VOUT, and GND bus
connections as wide as possible: These paths must be wide and direct as possible to
reduce any voltage drops on the input or output paths of the converter, thus maximizing
efficiency.
- Locate the buck inductor close to the
SW1, SW2, and SW3 pins: Use a short, wide connection trace from the converter SW
pins to the inductor. At the same time, minimize the length (and area) of this high-dv/dt
surface to help reduce capacitive coupling and radiated EMI. Connect the dotted terminal
of the inductor to the SW pins.
- Place the VCC and BOOT capacitors
close to the respective pins: The VCC and BOOT capacitors represent the supplies
for the internal low-side and high-side MOSFET gate drivers, respectively, and thus carry
high-frequency currents. Locate CVCC close to the VCC pin and place a GND via
at the return terminal to connect to the GND plane and thus back to IC GND at the exposed
pad. Connect CBOOT close to the CBOOT and SW4 pins.
- Place the feedback divider as close as
possible to the FB pin: Reduce noise sensitivity of the output voltage feedback path
by placing the resistor divider close to the FB pin, rather than close to the load. This
reduces the FB trace length and related noise coupling. The FB pin is the input to the
voltage-loop error amplifier and represents a high-impedance node sensitive to noise. The
connection to VOUT can be somewhat longer. However, this latter trace must not
be routed near any noise source (such as the switch node) that can capacitively couple
into the feedback path of the converter.
- Provide enough PCB area for proper
heatsinking: Use sufficient copper area to achieve a low thermal impedance
commensurate with the maximum load current and ambient temperature conditions. Provide
adequate heatsinking for the LM706A0-Q1 to keep the junction
temperature below 150°C. For operation at full rated load, the top-side ground plane is an
important heat-dissipating area. Use an array of heat-sinking vias to connect the exposed
pad (GND) of the package to the PCB ground plane. If the PCB has multiple copper layers,
connect these thermal vias to inner-layer ground planes. Make the top and bottom PCB
layers preferably with two-ounce copper thickness (and no less than one ounce).