ADM1066 Просмотр технического описания (PDF) - Analog Devices
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ADM1066 Datasheet PDF : 36 Pages
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ADM1066
Data Sheet
SEQUENCING ENGINE APPLICATION EXAMPLE
The application in this section demonstrates the operation of
the SE. Figure 28 shows how the simple building block of a single
SE state can be used to build a power-up sequence for a three-
supply system. Table 8 lists the PDO outputs for each state in
the same SE implementation. In this system, a good 5 V supply
on VP1 and the VX1 pin held low are the triggers required to
start a power-up sequence. The sequence next turns on the 3.3 V
supply, then the 2.5 V supply (assuming successful turn-on of the
3.3 V supply). When all three supplies have turned on correctly,
the PWRGD state is entered, where the SE remains until a fault
occurs on one of the three supplies or until it is instructed to go
through a power-down sequence by VX1 going high.
Faults are dealt with throughout the power-up sequence on a
case-by-case basis. The following three sections (the Sequence
Detector section, the Monitoring Fault Detector section, and
the Timeout Detector section) describe the individual blocks
and use the sample application shown in Figure 28 to
demonstrate the actions of the state machine.
Sequence Detector
The sequence detector block is used to detect when a step in
a sequence has been completed. It looks for one of the SE inputs
to change state, and is most often used as the gate for successful
progress through a power-up or power-down sequence. A timer
block that is included in this detector can insert delays into a
power-up or power-down sequence, if required. Timer delays
can be set from 10 μs to 400 ms. Figure 27 is a block diagram of
the sequence detector.
VP1
SUPPLY FAULT
DETECTION
SEQUENCE
DETECTOR
VX5
LOGIC INPUT CHANGE
OR FAULT DETECTION
WARNINGS
FORCE FLOW
(UNCONDITIONAL JUMP)
TIMER
INVERT
SELECT
Figure 27. Sequence Detector Block Diagram
Table 8. PDO Outputs for Each State
PDO Outputs
IDLE1 IDLE2
PDO1 = 3V3ON
0
0
PDO2 = 2V5ON
0
0
PDO3 = FAULT
0
0
EN3V3
1
0
0
EN2V5
1
1
0
If a timer delay is specified, the input to the sequence detector
must remain in the defined state for the duration of the timer
delay. If the input changes state during the delay, the timer is reset.
The sequence detector can also help to identify monitoring faults.
In the sample application shown in Figure 28, the FSEL1 and
FSEL2 states first identify which of the VP1, VP2, or VP3 pins
has faulted, and then they take appropriate action.
SEQUENCE
STATES
IDLE1
VX1 = 0
IDLE2
MONITOR FAULT
STATES
VP1 = 1
EN3V3
VP1 = 0
10ms
TIMEOUT
STATES
VP2 = 1
EN2V5
(VP1 + VP2) = 0
20ms
VP3 = 1
DIS3V3
VX1 = 1
(VP1 + VP2 + VP3) = 0
FSEL1
(VP1 +
VP2) = 0
PWRGD
DIS2V5
VP2 = 0
VX1 = 1
VX1 = 1
VP3 = 0
FSEL2
VP1 = 0
VP2 = 0
Figure 28. Sample Application Flow Diagram
DIS3V3
0
1
1
DIS2V5
1
0
1
PWRGD
1
1
0
FSEL1
1
1
1
FSEL2
1
1
1
Rev. F | Page 20 of 36
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