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Layout Considerations of Non-Isolated Switching Mode Power Supply. Presented by Henry Zhang Power Business Unit Linear Technology Corp. Oct. 2003. 1. General Discussion. Plan of the Power Supply Layout. In the system, power supply should be close to its load devices.
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Layout Considerations of Non-Isolated Switching Mode Power Supply Presented by Henry Zhang Power Business Unit Linear Technology Corp. Oct. 2003
Plan of the Power Supply Layout • In the system, power supply should be close to • its load devices. • Cooling fan should be close to the supply to limit • its component thermal stress. • Select the right number of layers and copper thickness • The large size passive components (inductors, bulk • capacitors) should not block air flow to power MOSFETs • Power supply designer should always works closely with • PCB designer on the critical layout design
Desired Layer #1 – Power Component Layer #2 – GND Layer #3 – Small Signal Layer #4 – Small signal / controller • Place ground or DC voltage layer between power layer and small signal layer 4-Layer PCB – Layer Placement Undesired Layer #1 – Power Component Layer #2 – Small Signal Layer #3 – GND Layer #4 – Small signal / controller Power Signal GND PCB capacitance High current loop Pulsating current loop
6-Layer PCB - Layer Placement Undesired Desired Layer #1 – Power Component Layer #1 – Power Component Layer #2 – Small signal Layer #2 – GND plane Layer #3 – GND plane Layer #3 – Small Signal Layer #4 – DC Voltage or GND plane Layer #4 – Small Signal Layer #5 – Small signal Layer #5 – DC Voltage or GND plane Layer #6 – Power Component / Controller Layer #6 – Power Component / Controller • DC power and ground planes function as AC reference planes. • As a general rule, the reference planes of a multi-layer PCB design should not be segmented.
Desired Undesired Reference Layer Reference Layer current current PWM IC MOSFET Coupled AC current return path Small Signal Traces on Reference Layer • If the small signal traces have to be routed on the reference layer, use short traces with proper direction:
Example: 1 Oz copper (1.4 mil thick), 0.5 inch wide (500mils), 2 inches long (2000mils), at 70 oC with 20A current: Rcopper = 2.3 m, Vcopper=46mV, Ploss=0.92W High current application - Recommend 2 oz or higher for external power layers Copper Thickness and PCB Resistance Copper resistivity (/cm): T – Copper temperature in oC Resistance of copper:
VIN+ ST High dv/dt node ESRin LF SW CHF Cin Vin ESRo SB Co D Vo R PGND Buck Converter Current Paths Continuous Current Pulsating Current • Identify the continuous and pulsating current paths • Pay special attention to pulsating current paths and high • dv/dt switching node
Trace Inductance VIN+ LF ST ST SB SW VIN+ D SW CHF CHF PGND SB D 0.1uF – 10uF Ceramic Capacitor Minimize this loop area PGND Parasitic Inductance in the Current Pathsand Example Layout (Buck) • Minimize loop between HF capacitor and MOSFETs • It is desirable to keep CHF, top FET and bottom FET on the same layer • Use multiple vias for power connection
Boost Converter Current Paths Continue Current High dv/dt node Pulsating Current LF D SW Vo+ Vo VIN CHF CIN Co SB Load PGND • Minimize the critical pulsating current loop on the output side
LF LF D SB SW SW D CHF Vo+ SB CHF PGND 0.1uF – 10uF Ceramic Capacitor Minimize this loop area PGND (b) (a) Output Noise Decoupling Capacitor (Boost) • Minimize the critical pulsating current loop on the output side
12V-to-2.5V/30A LTC3729 Supply Layout Example VIN+ (12V) VO+ (2.5V) LF1 QT CIN SW1 LTC3729 Co QB GND GND Co SW2 VIN+ VO+ (2.5V) (a)
Noise Problem @ Heavy Load Io = 0A Io >= 13.3 A vSW1 iLF1 vSW2 (c) (b)
Add 1uF/16V/X7R Io = 30 A Input Ceramic Capacitors Make a Difference (a) Io = 0A vSW1 iLF1 vSW2 (b) (c)
Desired - + R/C/D/L C - + C R/C/D/L FET Connected Via • Use wide / short copper trace for power components • Use multiple vias for inter-layer connections • Avoid improper use of “thermal relief” • Minimize resistance and inductance Land Patterns of Power Components Undesired Connected Via
3.3V/40A LTC3729 Layout Design Example High Current Trace
Air Flow Vo D GND L2 Vo Vin QB1 QB1 CHF1 Rsen2 Cout SW1 QT1 Rsen1 L1 Cout CIN D GND Cout Cout GND GND QB1 QB1 CIN CHF1 VIN L2 SW1 Rsen2 QT1 QT2 Rsen1 SW2 Cout CHF2 QB2 QB2 L1 GND D Internal GND Layer Internal GND Layer Examples of a 2-Phase DC/DC Power Stage
Separation of Input Paths Among Supplies Desired Undesired RPCB1 RPCB DC/DC #1 Cin Cin RPCB2 DC/DC #1 DC/DC #2 PGND PGND PGND DC/DC #2 PGND
Decoupling Capacitor and Separated Grounds LTC3729 RUN/SS TG1 R SEN1+ RSENSE C SW1 SEN1- R C EAIN SGND Island BG1 INTVCC ITH C C PGND SGND BG2 VDIFF PGND Plane SW2 R SEN2- TG2 RSENSE C SEN2+ R Shortest Distance
Signal Ground and Power Ground • Components connected to following pins use SGND: - EAIN, RUN/SS, ITH, UVADJ, PHAMD, PLLIN, PLLFTR, FCB, CLKOUT • Components connected to following pins use PGND: - BOOST, +5V, PGND • The SGND and PGND can be tied together underneath the IC.
Example LTC3731 PGND SGND SGND INTVCC C PGND PGND Vias Vias QFN Package Controller Layout • Exposed SGND pad must be soldered to PCB • Use multiple vias to connect SGND pad to both SGND and PGND layers • PGND pin also connects to SGND pad underneath the IC
Gate Driver Traces LTC3729 Route together QT BOOST1 TG1 SW1 INTVCC BG1 QB C PGND Automatically coupled AC ground return current PGND Plane
IC Signal Trace Width Following are the trace width values we use in Polyphase demo board: 20 mils – TG, BG, SW 25 mils - +5V, Vcc, PGND 15 mils – Current sensing, feedback, ITH, etc. 10 mils – Short traces that directly connected to IC pads
Current Sensing Traces RSENSE LF Vo+ Direct trace connection. Do NOT use via. LTC3729 This via should NOT touch any other internal Vo+ copper plane. R SENSE- C SENSE+ R • Kevin sensing of the current signal • Keep current sensing traces away from noisy traces / copper area or use ground layer for shielding.
Sensitive Traces and Noisy Traces • Most sensitive traces: • Current sensing (SENSE+/-), EAIN, ITH, SGND • Sense+ / - traces for each channel should be routed together • With minimum trace spacing. The filter capacitor should be as close to • IC pins as possible. The filter resistor should be close to filter capacitor. • Keep sensitive traces away from noisy traces. • Sensitive traces: Vos+/-, DIFFOUT, PLLFTR, CLKOUT • CLKOUT is a sensitive trace but it is also a noisy trace. So keep it away from • other small signal sensitive traces. • Most noisy traces: SW, TG, BOOST, BG • Keep them away from sensitive traces. • Avoid overlapping between large SW copper area and sensitive traces in two • neighborhood layers. • - For each channel, route the SW and TG trace together with minimum space.
Summary - Layout Checklist • Plan of the layout: • Location of the supply / load / bulk capacitors • # of layers / layer placement / copper thickness • Power stage layout: • Power component placement • Power component land patterns • Identify pulsating current paths • Decouple capacitor close to MOSFET • Short / wide copper trace and multiple vias for high current • Controller circuit layout: • Decoupling capacitors close to pins • Separate signal / power grounds • Current sensing • De-couple sensitive and noisy traces • Gate driver traces • Select proper trace width