MIC2589_05 Datasheet, PDF(16/29 Page) Micrel Semiconductor – Single-Channel, Negative High-Voltage Hot Swap Power Controller/Sequencer

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MIC2589_05 Datasheet, PDF (16/29 Pages) Micrel Semiconductor – Single-Channel, Negative High-Voltage Hot Swap Power Controller/Sequencer

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Micrel

MIC2589/MIC2595

Functional Description

Hot Swap Insertion

When circuit boards are inserted into systems carrying

live supply voltages (âhot swappedâ), high inrush

currents often result due to the charging of bulk

capacitance that resides across the circuit boardâs

supply pins. These current spikes can cause the

systemâs supply voltages to temporarily go out of

regulation causing data loss or system lock-up. In

more extreme cases, the transients occurring during a

hot swap event may cause permanent damage to

connectors or onboard components.

The MIC2589 and the MIC2595 are designed to

address these issues by limiting the maximum current

that is allowed to flow during hot swap events. This is

achieved by implementing a constant-current loop at

turn-on. In addition to inrush current control, the

MIC2589 and the MIC2595 incorporate input voltage

supervisory functions and user programmable

overcurrent protection, thereby providing robust

protection for both the system and the circuit board.

GATE Start-Up and Control

When the input voltage to the controller is between

the overvoltage and undervoltage threshold settings

(MIC2589) or is greater than the ON threshold setting

(MIC2595), a start cycle is initiated to deliver power to

the load. During the start-up cycle, the GATE pin of

the controller applies a constant charging current

(45ÂµA, nominal) to the gate of the external MOSFET,

charging the MOSFET gate from 0V to 10V,

referenced to VEE. An external capacitor (C2) can be

used to adjust and control the slew rate of the GATE

output, while resistor R4 can be used to minimize the

potential for parasitic high-frequency oscillations

occurring on the gate of the external MOSFET (M1).

See Typical Application circuit. The following

equation is used to approximate the expected inrush

current given the values of the capacitance at the gate

and the load (i.e., the gate of the external MOSFET

and the drain of the external MOSFET, respectively).

INRUSH =

C LOAD

CGATE

Ã IGATE(ON)

Active current limiting for the MIC2589/MIC2595 is

implemented by controlling the voltage on the GATE

pin via an internal feedback circuit. The

MIC2589/MIC2595 is defined to be in current limit

when the GATE output voltage level is between 2.5V

and 5.5V. Once in current limit, the GATE output

voltage is regulated to limit the load current to the

programmed value (ILIMIT).

Additionally, the

December 2005

overcurrent delay and the no-load detection timers

must be set accordingly to allow the output load to

fully charge during the start-up cycle. See the âCircuit

Breaker Functionâ and âNo-Load Detectionâ sections

for further details.

Resistor R4, in series with the power MOSFETâs gate,

may be required in some layouts to minimize the

potential for parasitic oscillations occurring in M1.

Note that resistance in this device of the circuit has a

slight

destabilizing

effect

upon

the

MIC2589/MIC2595âs current regulation loop. If

possible, use high-frequency PCB layout techniques

and use a dummy resistor (R4 = 0â¦) for the initial

evaluation. If during prototyping an R4 is required,

common values for R4 range between 4.7â¦ to 20â¦ for

various power MOSFETs.

Circuit Breaker Function

The MIC2589 and MIC2595 device family employs an

electronic circuit breaker that protects the external

power MOSFET and other system components

against large-scale faults, such as short circuits. The

current-limit threshold is set via an external resistor,

RSENSE, connected between the VEE and SENSE pins.

ILIMIT

VTRIP

R SENSE

An overcurrent filter period is set via a capacitor from

the CFILTER pin to ground (CFILTER) that determines

the length of the time period (tFLT) for which the device

remains in current limit before the circuit breaker is

tripped. This programmable delay prevents tripping of

the circuit breaker due to the large inrush current

charging bulk and distributed capacitive loads.

Whenever the voltage across RSENSE exceeds 50mV,

two things happen:

1. A constant-current regulation loop is engaged

which is designed to hold the voltage across

RSENSE equal to 50mV. This protects both the

load and the MIC2589/MIC2595 circuits from

excessively high currents. This current-

regulation loop will engage in less than 1Âµs

from the time at which the overcurrent trip

threshold on RSENSE is exceeded.

2. Capacitor CFILTER is charged up to an internal

VCFILTER(TRIP) threshold of 1.25V by

ICFILTER(CHARGE) an internal 95ÂµA current

source. If the voltage across CFILTER

crosses this threshold, the circuit breaker trips

and the GATE pin is immediately pulled low

by an internal current pull-down. This

operation turns off the MOSFET quickly and

disconnects the input from the load. The time

period that allows for the output to regulate in

M9999-120505

(408) 955-1690

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