SLUSFN3 July 2024 BQ25820
PRODUCTION DATA
Refer to the PDF data sheet for device specific package drawings
Proper layout of the components to minimize high frequency current path loops is important to prevent electrical and magnetic field radiation and high frequency resonant problems. Here is a PCB layout priority list for proper layout.
COMPONENTS | FUNCTION | IMPACT | GUIDELINES |
---|---|---|---|
Buck high side FET, Buck low side FET, input capacitors | Buck input loop | High frequency noise, ripple, efficiency | This path forms a high frequency switching loop due to the pulsating current at the input of the buck. Place components on the same side of the board. Minimize loop area to reduce parasitic inductance. Maximize trace width to reduce parasitic resistance. Place input ceramic capacitors close to the switching FETs. |
Sense resistors, switching FETs, inductor | Current path | Efficiency | The current path from input to output through the power stage and sense resistors has low impedance. Pay attention to via resistance if they are not on the same side. The number of vias can be estimated as 1- to 2-A per via for a 10-mil via with 1 oz. copper thickness. |
Switching FETs, inductor | Power stage | Thermal, efficiency | The switching FETs and inductor are the components with highest power loss. Allow enough copper area for heat dissipation. Multiple thermal vias can be used to connect more copper layers together and dissipate more heat. |
DRV_SUP, BTST1 capacitors | Switching FET gate drive | High frequency noise, parasitic ringing, gate drive integrity | The DRV_SUP capacitor is used to supply the power to drive the low side FETs. The BTST capacitors are used to drive the high side FETs. It is recommended to place the capacitors as close as possible to the IC. |
LODRV1 | Low side gate drive | High frequency noise, parasitic ringing, gate drive integrity | LODRV1 supplies the gate drive current to turn on the low side FETs. The return of LODRV1 is PGND. As current take the path of least impedance, a ground plane close to the low side gate drive traces is recommended. Minimize gate drive length and aim for at least 20-mil gate drive trace width. |
HIDRV1, SW1 (pin trace) | High side gate drive | High frequency noise, parasitic ringing, gate drive integrity | HIDRV1 supplies the gate drive current to turn on the high side FETs. The return of HIDRV1 are SW1. Route HIDRV1/SW1 pair next to each other to reduce gate drive parasitic inductance. Minimize gate drive length and aim for at least 20-mil gate drive trace width. |
Current limit resistors, FSW_SYNC resistor | IC programmable settings | Regulation accuracy, switching integrity | Pin voltage determines the settings for input current limit, output current limit and switching frequency. Ground noise on these could lead to inacuracy. Minimize ground return from these resistors to the IC ground pin. |
Input (ACP, ACN) and output (SRP, SRN) current sense | Current regulation | Regulation accuracy | Use Kelvin-sensing technique for input and output current sense resistors. Connect the current sense traces to the center of the pads, and run current sense traces as differential pairs, away from switching nodes. |
Input (ACUV), and output (FB, VO_SNS) voltage sensing | Voltage sense and regulation | Regulation accuracy | ACUV divider sets internal input voltage regulation in forward mode (VACUV_DPM). FB divider sets battery voltage regulation in forward mode (VFB_ACC). Route the top of the divider point to the target regulation location. Avoid routing close to high power switching nodes. |
Bypass capacitors | Noise filter | Noise immunity | Place lowest value capacitors closest to the IC. |