MIC2583 Micrel Semiconductor, MIC2583 Datasheet - Page 13

MIC2583

Manufacturer Part Number

MIC2583

Description

Single Channel Hot Swap Controllers

Manufacturer

Micrel Semiconductor

Datasheet

1.MIC2583.pdf (22 pages)

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Functional Description

Hot Swap Insertion

When circuit boards are inserted into live system backplanes

and supply voltages, high inrush currents can result due to the

charging of bulk capacitance that resides across the supply pins

of the circuit board. This inrush current, although transient in

nature, may be high enough to cause permanent damage to on

board components or may cause the system’s supply voltages

to go out of regulation during the transient period which may

result in system failures. The MIC2582 and MIC2583 act as a

controller for external N-Channel MOSFET devices in which the

gate drive is controlled to provide inrush current limiting and

output voltage slew rate control during hot plug insertions.

Power Supply

VCC is the supply input to the MIC2582/83 controller with a

voltage range of 2.3V to 13.2V. The VCC input can withstand

transient spikes up to 20V. In order to ensure stability of the

supply voltage, a minimum 0.47 F capacitor from VCC to

ground is recommended. Alternatively, a low pass filter, shown

in the typical application circuit (see Figure 1), can be used to

eliminate high frequency oscillations as well as help suppress

transient spikes.

Also, due to the existence of an undetermined amount of

parasitic inductance in the absence of bulk capacitance along

the supply path, placing a Zener diode at the VCC of the

controller to ground in order to provide external supply transient

protection is strongly recommended for relatively high current

applications ( 3A). See Figure 1.

Start-Up Cycle

Supply Contact Delay

During a hot insert of a PC board into a backplane or when the

supply (VCC) is powered up, as the voltage at the ON pin rises

above its threshold (1.24V typical), the MIC2582/83 first checks

that both supply voltages are above their respective UVLO

thresholds. If so, the device is enabled and an internal 2.5 A

current source begins charging capacitor C

initiate a start-up sequence. Once the start-up delay (t

elapses, the CPOR pin is pulled immediately to ground and a

17 A current source begins charging the GATE output to drive

the external MOSFET that switches V

grammed contact start-up delay is calculated using the follow-

ing equation:

where the start-up delay timer threshold (V

the Power-On Reset timer current (I

2 for some typical supply contact start-up delays using several

standard value capacitors. As the GATE voltage continues

ramping toward its final value (V

(See Load Capacitance/Gate Capacitance Dominated Start-

up sections), a second CPOR timing cycle begins if: 1)/FAULT

is high and 2)CFILTER is low (i.e., not an overvoltage,

undervoltage lockout, or overcurrent state). This second timing

cycle (t

threshold (V

is valid. See Figure 3 in the Timing Diagrams. When the power

April 2003

MIC2582/MIC2583

START

POR

) begins when the voltage at the FB pin exceeds its

). This condition indicates that the output voltage

POR

START

CPOR

+ V

0.12 C

CPOR

) at a defined slew rate

) is 2.5 A. See Table

START

to V

POR

OUT

( F)

) is 0.3V, and

to 0.3V to

. The pro-

START

(1)

)

supply is already present (i.e., not a “hot swapping” condition)

and the MIC2582/83 device is enabled by applying a logic high

signal at the ON pin, the GATE output begins ramping immedi-

ately as the first CPOR timing cycle is bypassed. Active current

regulation is employed to limit the inrush current transient

response during start-up by regulating the load current at the

programmed current limit value (See Current Limiting and Dual-

Level Circuit Breaker section). The following equation is used

to determine the nominal current limit value:

where V

in the electrical table and R

set the desired current limit. There are two basic start-up modes

for the MIC2582/83: 1) Start-up dominated by load capacitance

and 2) start-up dominated by total gate capacitance. The

magnitude of the inrush current delivered to the load will

determine the dominant mode. If the inrush current is greater

than the programmed current limit (I

is dominant. Otherwise, gate capacitance is dominant. The

expected inrush current may be calculated using the following

equation:

where I

capacitance, and C

the external MOSFET and any external capacitor connected

from the MIC2582/83 GATE pin to ground).

Load Capacitance Dominated Start-Up

In this case, the load capacitance (C

cause the inrush current to exceed the programmed current

limit but is less than the fast-trip threshold (or the fast-trip

threshold is disabled, ‘M’ option). During start-up under this

condition, the load current is regulated at the programmed

current limit value (I

voltage rises to its final value. The output slew rate and

equivalent GATE voltage slew rate is computed by the following

equation:

where I

quently, the value of C

the overcurrent response time, t

needed for the output to reach its final value. For example, given

a MOSFET with an input capacitance C

load capacitance dominates as determined by the calculated

INRUSH > I

mined from Equation 4 is:

and the resulting t

approximately 4.5ms. (See Power-On Reset and Overcurrent

Timer Delays section to calculate t

Output Voltage Slew Rate, dV

LOAD

INRUSH I

Output Voltage Slew Rate, dV

LIM

is 2200 F, and I

GATE

LIM

TRIPSLOW

LIM

is the programmed current limit value. Conse-

is the GATE pin pull-up current, C

TRIPSLOW

. Therefore, the output voltage slew rate deter-

SENSE

OCSLOW

GATE

is the current limit slow trip threshold found

GATE

LIM

FILTER

LIM

) and held constant until the output

is the total GATE capacitance (C

is set to 6A with a 12V input, then the

SENSE

needed to achieve a 12V output is

LOAD

GATE

50mV

SENSE

must be selected to ensure that

OUT

is the selected value that will

OCSLOW

LIM

17 A

LOAD

/dt

OUT

), then load capacitance

ISS

/dt

, exceeds the time

MIC2582/MIC2583

) is large enough to

2200 F

= C

)

LOAD

GATE

LOAD

LIM

= 4700pF,

is the load

(2)

(3)

2.73

Micrel

ISS

(4)

MIC2583 Micrel Semiconductor, MIC2583 Datasheet - Page 13

MIC2583

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