ZHCSOO7A August 2021 – November 2021 TPSM8A28 , TPSM8A29
PRODUCTION DATA
When the EN pin voltage rises above the enable threshold voltage (typically 1.22 V) and VIN rises above the VIN UVLO rising threshold, the device enters its internal power-up sequence. The EN to first switching delay is specified in the Start-Up section in the Electrical Characteristics table.
When using the internal VCC LDO, the internal power-up sequence includes three sequential steps. During the first period, the VCC voltage is charged up on the VCC bypass capacitor by a 11-mA current source. The length of this VCC LDO start-up time varies with the capacitance on the VCC pin. However, if VIN voltage ramps up very slowly, the VCC LDO output voltage is limited by theVIN voltage level, so the VCC LDO start-up time can be extended longer. Since the VCC LDO start-up time is relatively long, the internal VINTREF build-up happens and finishes during this period. Once the VCC voltage crosses above the VCC UVLO rising threshold (typically 2.87 V), the device moves to the second step, power-on delay. The MODE pin setting detection, SS/REFIN pin detection, and control loop initialization are finished within this 285-μs delay. The soft-start ramp starts when the 285-μs power-on delay finishes. During the soft-start ramp power stage, switching does not happen until the SS/REFIN pin voltage reaches 50 mV. This introduces a SS delay, which varies with the external capacitance on the SS/REFIN pin.
Figure 7-1 shows an example where the VIN UVLO rising threshold is satisfied earlier than the EN rising threshold. In this scenario, the VCC UVLO rising threshold becomes the gating signal to start the internal power-up sequence, and the sequence between VIN and EN does not matter.
When using an external bias on the VCC pin, the internal power-up sequence still includes three sequential steps. The first period is much shorter since the VCC voltage is built up already. A 100-µs period allows the internal references start up and stabilize. This 100-µs period includes not only the 0.6-V VINTREF, but also all of the other reference voltages for various functions. The device then moves to the second step, power-on delay. The MODE pin setting detection, SS/REFIN pin detection, and control loop initialization are finished within this 285-μs delay. The soft-start ramp starts when the 285-μs power-on delay finishes. During the soft-start ramp power stage, switching does not happen until the SS/REFIN pin voltage reaches 50 mV. This introduced a SS delay, which varies with the external capacitance on the SS/REFIN pin.
Figure 7-2 shows an example where both the VIN UVLO rising threshold and EN rising threshold are satisfied later than the VCC UVLO rising threshold. In this scenario, the VIN UVLO rising threshold or EN rising threshold, whichever is satisfied later, becomes the gating signal to start the internal power-up sequence.
The EN pin has an internal filter to avoid unexpected ON or OFF due to small glitches. The time constant of this RC filter is 5 µs. For example, when applying a 3.3-V voltage source on the EN pin, which jumps from 0 V to 3.3 V with ideal rising edge, the internal EN signal reaches 2.086 V after 5 µs, which is 63.2% of applied 3.3-V voltage level.
A internal pulldown resistor is implemented between the EN pin and AGND pin. To avoid impact to the EN rising/falling threshold, this internal pulldown resistor is set to 6.5 MΩ. With this pulldown resistor, floating the EN pin before start-up keeps the device under disabled state. During nominal operation when the power stage switches, this large internal pulldown resistor may not have enough noise immunity to hold the EN pin low.
The recommended operating condition for EN pin is maximum 5.5 V. Do not connect the EN pin to the VIN pin directly.