X80200 Datasheet, PDF(7/16 Page) Intersil Corporation – Power Supply Swquencer with Power-up System Mnitoring

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X80200 Datasheet, PDF (7/16 Pages) Intersil Corporation – Power Supply Swquencer with Power-up System Mnitoring

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X80200, X80201, X80202, X80203, X80204

Principles of Operation

Power Sequencing Control (PSC)

The Intersil X80200 supports a variety of sequencing

applications. The sequencing can be voltage-based or time-

based. Some examples are shown in Figure , Figure , and

Figure in the Applications section. The X80200 allows for

designs that can control the power sequencing of up to three

voltage supplies. For systems with more than three supplies,

the X80200 may be cascaded.

Basic Functions

VDDH is the primary voltage for the X80200. Once VDDH

rises above the primary undervoltage lockout level (UVLOH)

for time tPURST, the READY output goes HIGH indicating

that the supply power is good. By connecting READY

directly to GATEH_EN, the GATE_H output goes high

immediately, turning on the power FET connected in series

with VDDH. The system primary voltage may be delayed by

using an external RC circuit between READY and

GATEH_EN.

VDDH must be stable before VDDM and VDDL supplies are

monitored and power sequencing begins.

The second supply voltage (I/O supply) is monitored by the

VDDM pin. VDDM must be greater than the I/O supply

undervoltage lockout level (UVLOM) prior to any activation of

the GATE_M output. The VDDM voltage is used to turn on

the charge pump that drives the GATE_M output.

The third supply (core supply) is monitored by the VDDL pin.

VDDL must be greater than the core supply undervoltage

lockout level (UVLOL) prior to any activation of the GATE_L

output. The VDDL voltage is used to turn on the charge

pump that drives the GATE_M output.

Power Sequencing Functions

X80200 provides two options for power sequencing. In time

based sequencing, the ENS (Enable Sequence) input

signals that the core and I/O voltages are to turn on with a

fixed time relationship. In voltage based sequencing, the

SETV (Set Voltage) initiates turn-on of the core voltage. The

I/O voltage remains off until the core voltage reaches a set

threshold.

In both cases the X80200 uses a core-voltage first and core

voltage-last power up/down algorithm.

TIME-BASED POWER SEQUENCING

A rising edge (LOW to HIGH) transition of the ENS pin turns

on the charge pump that drives the GATE_L output.

A falling edge (HIGH to LOW) transition of the ENS signal

turns off the charge pump that drives the GATE_M output.

This technique provides a âforcedâ core-voltage-first power

up and core-voltage-last power down algorithm. The ENS

signal does not control the ramp up/down rates of the

GATE_M or GATE_L outputs.

In the absence of an externally provided ENS signal, the

ENS pin can be connected in a number of different ways.

â¢ ENS can connect to the VDDH pin. In this case, the

GATE_H and GATE_L outputs are enabled at the same

time. GATE_H could be delayed by using an external RC

timer between READY and GATEH_EN to provide a

sequence where VDDL is the first supply voltage applied

to the system.

â¢ ENS can connect to a delayed READY signal, so that the

VDDL voltage follows the VDDH voltage by a fixed time.

â¢ ENS can connect to the system side of the VDDH FET, so

the VDDL voltage will follow immediately after the primary

supply is applied to the system.

See "Functional Description" on page 7 for details on timing

and ramp-up.

VOLTAGE-BASED POWER SEQUENCING

In this configuration, the drain of the âLâ MOSFET is

connected to the VFB input of the X80200, the ENS pin is

tied to ground and a resistor divider provides a reference

voltage to the REF pin.

A LOW to HIGH transition of the SETV pin turns on the

GATE_L output. This turns on the âLâ MOSFET. Once the

drain of this FET reaches the REF level, GATE_M turns on.

Since the trigger for the GATE_M output is selected by a

threshold level, the user has the ability to specify relative

core and I/O voltage sequencing.

System Monitoring and Remote Shutdown

The X80200 Status Register contains fault detection bits that

indicate the status of the GATE_H, GATE_M, and GATE_L

pins. These bits are Stat_GATEH, Stat_GATEM, and

Stat_GATEL. The status register can be read via 2-wire bus.

This feature allows for system monitoring of the power

sequencing of supplies.

The system can turn off the FETs by writing to the Remote

Shutdown Register through the 2-wire interface. There are

three turn-off selections. See "Remote Shutdown Register

(RSR) (Volatile)" on page 10 for more details.

Functional Description

Voltage Inputs. The X80200 has three voltage monitors for

power sequencing: the VDDH (primary voltage), VDDM (I/O

voltage), and VDDL (core voltage). These voltage monitors

operate independently of each other.

PRIMARY VOLTAGE VDDH

This voltage is the primary voltage for the device and is

required before X80200 can power sequence VDDM and

VDDL. As VDDH powers up, it is compared to an internal

UVLOH reference. This undervoltage lockout level is preset

at the factory. For information on this setting, see Ordering

Information. For custom programmed levels, contact Intersil.

FN8154.0

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