ZHCSNW7 April 2021 LP8758-EA
PRODUCTION DATA
The buck converter cores can be enabled when the device is in STANDBY or ACTIVE state. There are two ways to enable and disable the buck converter cores:
If the EN1/2 control pins are used for enable and disable, the delay from the control signal rising edge to start-up is set by BUCKx_DELAY.BUCKx_STARTUP_DELAY[3:0] bits and the delay from control signal falling edge to shutdown is set by BUCKx_DELAY.BUCKx_SHUTDOWN_DELAY[3:0] bits. The delays are valid only for EN1/2 signal and not for control with BUCKx_CTRL1.EN_BUCKx bit. The delay time implemented by EN1/2 has overall ±10% timing accuracy.
The control of the converter cores (with 0 ms delays) is shown in Table 7-1.
CONTROL METHOD | ROW | EN_BUCKx | BUCKx_CTRL1 EN_PIN_CTRLx | BUCKx_CTRL1 EN_PIN_SELECTx | BUCKx_CTRL1 EN_ROOF_FLOORx | EN1 PIN | EN2 PIN | BUCKx OUTPUT VOLTAGE |
---|---|---|---|---|---|---|---|---|
Enable or disable control with EN_BUCKx bit | 1 | 0 | Don't Care | Don't Care | Don't Care | Don't Care | Don't Care | Disabled |
2 | 1 | 0 | Don't Care | Don't Care | Don't Care | Don't Care | BUCKx_VOUT.BUCKx_VSET[7:0] | |
Enable or disable control with EN1 pin | 3 | 1 | 1 | 0 | 0 | Low | Don't Care | Disabled |
4 | 1 | 1 | 0 | 0 | High | Don't Care | BUCKx_VOUT.BUCKx_VSET[7:0] | |
Enable or disable control with EN2 pin | 5 | 1 | 1 | 1 | 0 | Don't Care | Low | Disabled |
6 | 1 | 1 | 1 | 0 | Don't Care | High | BUCKx_VOUT.BUCKx_VSET[7:0] | |
Roof or floor control with EN1 pin | 7 | 1 | 1 | 0 | 1 | Low | Don't Care | BUCKx_FLOOR_VOUT.BUCKx_FLOOR_VSET[7:0] |
8 | 1 | 1 | 0 | 1 | High | Don't Care | BUCKx_VOUT.BUCKx_VSET[7:0] | |
Roof or floor control with EN2 pin | 9 | 1 | 1 | 1 | 1 | Don't Care | Low | BUCKx_FLOOR_VOUT.BUCKx_FLOOR_VSET[7:0] |
10 | 1 | 1 | 1 | 1 | Don't Care | High | BUCKx_VOUT.BUCKx_VSET[7:0] |
The following buck configuration bit settings allows the device to enable or disable the corresponding buck using the ENx pin:
When the ENx pin is low, Table 7-1 row 3 (or 5) is valid, and the converter core is disabled. By setting ENx pin high, Table 7-1 row 4 (or 6) is valid, and the converter core is enabled with required voltage.
If a converter core is enabled all the time, and the ENx pin controls selection between the two voltage levels, then the following configuration is used:
When the ENx pin is low, Table 7-1 row 7 (or 9) is valid, and the core is enabled with a voltage defined by BUCKx_FLOOR_VOUT.BUCKx_FLOOR_VSET[7:0] bits. Setting the ENx pin high, Table 7-1 row 8 (or 10) is valid, and the core is enabled with a voltage defined by BUCKx_VOUT.BUCKx_VSET[7:0] bits.
If the core is controlled by I2C writings, the BUCKx_CTRL1.EN_PIN_CTRLx bit is set to 0. The enable or disable is controlled by the BUCKx_CTRL1.EN_BUCKx bit, and when the regulator is enabled, the output voltage is defined by the BUCKx_VOUT.BUCKx_VSET[7:0] bits. The Table 7-1 rows 1 and 2 are valid for I2C controlled operation (ENx pins are ignored).
The buck converter core is enabled by the ENx pin or by I2C writing as shown in Figure 7-4. The soft-start circuit limits the in-rush current during start-up. Output voltage increase rate is around 5 mV/μsec during soft-start. When the output voltage rises to approximately 0.3 V, the output voltage becomes slew-rate controlled. If there is a short circuit at the output, and the output voltage does not increase above a 0.35-V level in 1 ms, the converter core is disabled, and interrupt is set. When the output voltage reaches the powergood threshold level the INT_BUCK_x.BUCKx_PG_INT interrupt flag is set. The powergood interrupt flag can be masked using BUCK_x_MASK.BUCKx_PG_MASK bit.
The ENx input pins have integrated pull-down resistors. The pull-down resistors are enabled by default and host can disable those with CONFIG.ENx_PD bits.