SPRUJ28E November 2021 – September 2024 AM68 , AM68A , TDA4AL-Q1 , TDA4VE-Q1 , TDA4VL-Q1
The error pin output (ERR_O) is used to signal an external agent that it needs to (or may need to) intervene because of an error. Each error event input can be programmed, via software, to influence the error pin output (via the ESM_PIN_EN_SET_j register). The error pin output is active low or PWM based on the ESM_EN[7-4] PWM_EN field. This bit field should only be modified when the ESM is disabled, based on the ESM_EN register.
During Power-Оn Reset (POR), the error pin is active (asserted low) and the device drives this via a weak internal pull-down. The I/O is under the control of the device. When POR is removed from the ESM, it will be driving the error pin so the device can hand over control to the ESM. The user may also add an external pull-down that is only active when the device is in reset.
During a warm reset the state of the error pin is unchanged, that is the error pin logic is only reset by a POR. The device leaves the I/O active during a warm reset.
The ESM has also a software error forcing capability on the error pin. That is, a force error can be set via the ESM_EN[3-0] KEY bit field.
The isolation value for the ERR_O output of ESM is active (0). This is intended and supposed to protect against an accidental transition to a low power state. If the actual low power mode transition is intended, the PMIC should be made aware by software to ignore the ESM error signal. Otherwise device resets will be asserted from companion chip.
Figure 12-496 describes the behavior of the error pin. Not shown is that a reset (Power-On-Reset only) will immediately transition the error pin to the ESM_RESET state and a Global Soft Reset will immediately transition the error pin to the ESM_IDLE state. A pending error interrupt event is any error event with the raw state set and the error pin Influence enabled. There are two types of "clear" events associated with servicing the error pin. The first is to clear the status of the pending event (see Section 12.10.2.3.1 for how to clear level and pulse pending events). The second is the CLEAR event meant to de-assert the error pin.
If an error event happens that has been programmed to influence the error pin, the error pin will assert (active low) for a minimum time (as programmed by the ESM_PIN_CNTR_PRE register). In order for the error pin to de-assert, the following 3 things must happen:
Step 3 should happen after step 2, but either (or both) of these steps may happen before or after step 1.
Figure 12-497 shows a typical error pin assertion.
If, during the minimum time, CLEAR is written to the error key, then the error pin will de-assert after the minimum time interval, as shown in Figure 12-498.
If CLEAR is not written till after the minimum time interval, the error pin will de-assert when CLEAR is written. This is regardless of whether the error interrupt event itself is removed before or after the minimum time interval, as shown by the dotted line in Figure 12-499.
When in the ESM_ERROR state and a CLEAR event happen, if there are still pending error events, the ESM stays in the ESM_ERROR state with the error pin asserted. Multiple error events when in the ESM_ERROR state do not reset the minimum time interval counter as shown in Figure 12-500.
A CLEAR event causes a re-evaluation of whether there are any pending error events. As such, a single CLEAR can be used to clear the error pin after multiple error events. Multiple CLEAR events can occur (such as the one with the dotted arrow shown in Figure 12-501), but are not necessary. No matter how many error events occur nor when (or how many) CLEAR events occur, the error pin will always be asserted for at least the minimum time interval
If all error events are cleared and the ESM is in the ESM_WAIT state, waiting for the minimum time interval to expire, and a new error interrupt event occurs, the ESM will go back to the ESM_ERROR state. The minimum time interval will not reset, but a new CLEAR event will be required as shown in Figure 12-502.
Table 12-434 shows some common scenarios of how the error pin as well as the two associated registers (ESM_PIN_CTRL and ESM_PIN_STS) will be set.
Scenario | Error Pin State Value | ESM_PIN_CTRL[3-0] KEY | ESM_PIN_STS[0] VAL status value | Additional Notes |
---|---|---|---|---|
POR Asserted | 0 | N/A | N/A | Registers are inaccessible. Device disables the I/O and pulls down internally. |
After de-assertion of POR | 1 | 0x0 (Normal Mode) | 0x0 | - |
After de-assertion of Warm Reset (error was not asserted when reset asserted) | 1 | 0x0 (Normal Mode) | 0x0 | - |
After de-assertion of Warm Reset (error was asserted when reset asserted) | 0 | 0x0 (Normal Mode) | 0x1 | - |
Force error pin | 0 | 0xA (Force Error Mode) | 0x0 | Forcing error on the pin via software. |