SLUSFB0 August 2024 BQ25758S
PRODUCTION DATA
Refer to the PDF data sheet for device specific package drawings
PIN | I/O | DESCRIPTION | |
---|---|---|---|
NAME | NO. | ||
SCL | 1 | DI | I2C Interface Clock – Connect SCL to the logic rail through a 10-kΩ resistor. |
SDA | 2 | DIO | I2C Interface Data – Connect SDA to the logic rail through a 10-kΩ resistor. |
INT | 3 | DO | Open Drain Interrupt Output – Connect the INT pin to a logic rail via 10-kΩ resistor. The INT pin sends an active low, 256-μs pulse to host to report the controller device status and faults. |
STAT | 4 | DO | Open Drain Status Output – Connect to the pull up rail via 10-kΩ resistor. The STAT pin function can be disabled when DIS_STAT_PIN bit is set to 1. When disabled, this pin can be used as a general purpose indicator via the FORCE_STAT_ON bit. |
NC | 5 | - | No Connect - Leave this pin floating, do not tie to PGND |
PG/STAT3 | 6 | DO | Open Drain Active Low Power Good Indicator – Connect to the pull up rail via 10-kΩ resistor. LOW indicates a good input source if VAC is within the programmed ACUV / ACOV operating window. The PG pin function can be disabled when DIS_PG_PIN bit is set to 1. When disabled, this pin can be used as a general purpose indicator via the FORCE_STAT3_ON bit. |
CE/STAT4 | 7 | DIO | Active Low Enable Pin – Power conversion is enabled when EN_CHG bit is 1 and CE pin is LOW. CE pin must be pulled HIGH or LOW, do not leave floating. The CE pin function can be disabled when DIS_CE_PIN bit is set to 1. When disabled, this pin can be used as a general purpose indicator via the FORCE_STAT4_ON bit. |
TS / NC | 8 | AI | Temperature
Qualification Voltage Input – This pin's function is normally disabled. If not
needed, leave this pin floating. To enable pin functionality, set EN_TS register bit to 1. Connect a negative temperature coefficient thermistor. Program temperature window with a resistor divider from REGN to TS to PGND. Power conversion suspends when TS pin voltage is out of range. Recommend 103AT-2 10-kΩ thermistor. |
IOUT | 9 | AI | Output Current Limit Setting – IOUT pin sets the maximum output current, and can be used to monitor the output current. A programming resistor to PGND is used to set the output current limit as IIOUT = KIOUT / RIOUT. When the device is under output current regulation, the voltage at IOUT pin is VREF_IOUT. When IOUT pin voltage is less than VREF_IOUT, the actual output current can be calculated as: IOUT = KIOUT x VIOUT / ( RIOUT x VREF_IOUT). The actual output current limit is the lower of the limits set by IOUT pin or the IOUT_REG register bits. This pin function can be disabled when EN_IOUT_PIN bit is 0. If IOUT pin is not used, this pin should be pulled to PGND, do not leave floating. |
IIN | 10 | AI | Input Current Limit Setting – IIN pin sets the maximum input current, and can be used to monitor the input current. A programming resistor to PGND is used to set the input current limit as ILIM = KILIM / RIIN. When the device is under input current regulation, the voltage at IIN pin is VREF_IILIM. When IIN pin voltage is less than VREF_ILIM, the actual input current can be calculated as: IAC = KILIM x VIIN / ( RIIN x VREF_ILIM). The actual input current limit is the lower of the limits set by IIN pin or the IAC_DPM register bits. This pin function can be disabled when EN_IIN_PIN bit is 0. If IIN pin is not used, this pin should be pulled to PGND, do not leave floating. |
NC | 11 | - | No Connect - Leave this pin floating , do not tie to PGND |
VO_SNS | 12 | AI | Output Voltage Sensing – Kelvin connect directly to the output voltage regulation point. |
SRN | 13 | AI | Current-Sense Resistor, Negative Input – A 0.47-μF ceramic capacitor is placed from SRN to SRP to provide differential-mode filtering. An optional 0.1-μF ceramic capacitor is placed from the SRN pin to PGND for common-mode filtering. |
SRP | 14 | AI | Current-Sense Resistor, Positive Input – A 0.47-μF ceramic capacitor is placed from SRN to SRP to provide differential-mode filtering. A 0.1-μF ceramic capacitor is placed from the SRP pin to PGND for common-mode filtering. |
NC | 15 | - | No Connect - Leave this pin floating, do not tie to PGND |
NC | 16 | - | No Connect - Leave this pin floating, do not tie to PGND |
MODE | 17 | AI | Mode Programming resistor – Connect a resistor from this pin to PGND to select between buck-boost or buck-only operation. Refer to MODE Pin Configuration section for more details. |
SW2 | 18 | AI | Boost Side Half Bridge Switching Node – |
HIDRV2 | 19 | AO | Boost Side High-Side Gate Driver – Connect to the boost high-side N-channel MOSFET gate. |
BTST2 | 20 | P | Boost Side High-Side Power MOSFET Gate Driver Power Supply – Connect a capacitor between BTST2 and SW2 to provide bias to the high-side MOSFET gate driver. |
LODRV2 | 21 | AO | Boost Side Low-Side Gate Driver – Connect to the boost low-side N-channel MOSFET gate. |
PGND | 22 | - | Power Ground Return – The high current ground connection for the low-side gate drivers. |
DRV_SUP | 23 | P | Gate Drive Supply Input – Voltage on this pin is used to drive the gates of buck-boost converter switching FET. Connect a 4.7-μF ceramic capacitor from DRV_SUP to power ground. REGN LDO voltage can be used as the gate driver supply for all switching FETs by connecting REGN to DRV_SUP pin. In high-voltage applications, it is possible to directly provide the DRV_SUP voltage with an external supply up to 12 V to achieve higher switching efficiency. See Section 7.3.3.3 for more details. |
REGN | 24 | P | Internal Linear Regulator Output – Connect a 4.7-μF ceramic capacitor from REGN to power ground. REGN LDO voltage can be used as the gate driver supply for all switching FETs by connecting REGN to DRV_SUP pin. In high-voltage applications, it is possible to directly provide the DRV_SUP voltage with an external supply up to 12 V to achieve higher switching efficiency. See Section 7.3.3.3 for more details. |
LODRV1 | 25 | AO | Buck Side Low-Side Gate Driver – Connect to the buck low-side N-channel MOSFET gate. |
BTST1 | 26 | P | Buck Side High-Side Power MOSFET Gate Driver Power Supply – Connect a capacitor between BTST1 and SW1 to provide bias to the high-side MOSFET gate driver. |
HIDRV1 | 27 | AO | Buck Side High-Side Gate Driver – Connect to the buck high-side N-channel MOSFET gate. |
SW1 | 28 | AI | Buck Side Half Bridge Switching Node – |
ACN | 29 | AI | Adapter Current-Sense Resistor, Negative Input A 0.47-μF ceramic capacitor is placed from ACN to ACP to provide differential-mode filtering. An optional 0.1-μF ceramic capacitor is placed from the ACN pin to PGND for common-mode filtering. |
ACP | 30 | AI | Adapter Current-Sense Resistor, Positive Input A 0.47-μF ceramic capacitor is placed from ACN to ACP to provide differential-mode filtering. A 0.1-μF ceramic capacitor is placed from the ACP pin to PGND for common-mode filtering |
NC | 31 | - | No Connect - Leave this pin floating, do not tie to PGND |
VAC | 32 | P | Input Voltage Detection and Power VAC is the input bias to power the IC. Connect a 1µF capacitor from pin to PGND. When Reverse Mode is enabled, pin 32 is regulated to VAC_REV. |
33 | |||
ACUV | 34 | AI | VAC Undervoltage Comparator Input – Connect a resistor divider from VAC to PGND to program the undervoltage protection. When this pin falls below VREF_ACUV, the device stops operation. The hardware limit for input voltage regulation reference is VACUV_DPM. The actual input voltage regulation setting is the higher of the pin-programmed value and the VAC_DPM register value. If ACUV programming is not used, pull this pin to VAC, do not leave floating. |
ACOV | 35 | AI | VAC Overvoltage Comparator Input – Connect a resistor divider from VAC to PGND to program the overvoltage protection. When this pin rises above VREF_ACOV, the device stops operation. If ACOV programming is not used, pull this pin to PGND, do not leave floating. |
FSW_SYNC | 36 | DAI | Switching Frequency and Synchronization Input – An external resistor is connected to the FSW_SYNC pin and PGND to set the nominal switching frequency. This pin can also be used to synchronize the PWM controller to an external clock. |
Thermal Pad | 37 | - | Exposed pad beneath the IC – Always solder the thermal pad to the board, and have vias on the thermal pad plane star-connecting to PGND and ground plane for high-current power converter. It also serves as a thermal pad to dissipate the heat. |