SLVSFU1D April 2023 – December 2024 TPS62874-Q1 , TPS62875-Q1 , TPS62876-Q1 , TPS62877-Q1
PRODUCTION DATA
The device can control the inductor current in three different ways to regulate the output:
During PWM-CCM operation, the device switches at a constant frequency and the inductor current is continuous (see Figure 8-2). PWM operation achieves the lowest output voltage ripple and the best transient performance.
During PWM-DCM operation the device switches at a constant frequency and the inductor current is discontinuous (see Figure 8-3). In this mode the device controls the peak inductor current to maintain the selected switching frequency while still being able to regulate the output.
During PFM-DCM operation the device keeps the peak inductor current constant (at a level corresponding to the minimum on-time of the converter) and skips pulses to regulate the output (see Figure 8-4). The switching pulses that occur during PFM-DCM operation are synchronized to the internal clock.
.Use Equation 1 to calculate the output current threshold at which the device enters PFM-DCM:
The following figure shows how this threshold typically varies with VIN and VOUT for a switching frequency of 2.25MHz
Configure the device to use either Forced-PWM (FPWM) mode or Power-Save Mode (PSM):
Table 8-1 shows the function table of the MODE/SYNC pin and the FPWMEN bit in the CONTROL1 register, which control the operating mode of the device.
MODE/SYNC Pin | FPWMEN Bit | Operating Mode | Remark |
---|---|---|---|
Low | 0 | PSM | Do not use in a stacked configuration |
1 | FPWM | ||
High | X | FPWM | |
Sync Clock | X | FPWM |