ISL6140_14 Datasheet, PDF(8/19 Page) Intersil Corporation – Negative Voltage Hot Plug Controller

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ISL6140_14 Datasheet, PDF (8/19 Pages) Intersil Corporation – Negative Voltage Hot Plug Controller

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ISL6140, ISL6150

be selected based on several criteria: maximum

voltage expected on the input supply (including

transients) as well as transients on the output side;

maximum current expected; power dissipation and/or

safe-operating-area considerations (due to the quick

overcurrent latch, power dissipation is usually not a

problem compared to systems where current limiting is

used; however, worst case power is usually at a level

just below the overcurrent shutdown). Other

considerations include the gate voltage threshold which

affects the rDS(ON) (which in turn, affects the voltage

drop across the FET during normal operation), and the

maximum gate voltage allowed (the IC clamp output is

clamped to ~14V).

R1 - is the overcurrent sense resistor; if the input

current is high enough, such that the voltage drop

across R1 exceeds the SENSE comparator trip point

(50mV nominal), the GATE pin will go low, turning off

the FET, to protect the load from the excessive current.

A typical value for R1 is 0.02Î©; this sets an overcurrent

trip point of I = V/R = 0.05/0.02 = 2.5A. So, to choose

R1, the user must first determine at what level of

current it should trip. Take into account worst case

variations for the trip point (50mV Â±10mV = Â±20%),

and the R1 resistance (typically 1% or 5%). Note that

under normal conditions, there will be a voltage drop

across the resistor (V = IR), so the higher the resistor

value, the bigger the voltage drop. Also note that the

overcurrent should be set above the inrush current

level (plus the load current); otherwise, it will latch off

during that time (the alternative is to lower the in-rush

current further). One rule of thumb is to set the

overcurrent 2-3 times higher than the normal current

(see Equation 1).

R1 = V â IOC = 0.05V/IOC(typical = 0.02Î©)

(EQ. 1)

CL - is the sum of all load capacitances, including the

loadâs input capacitance itself. Its value is usually

determined by the needs of the load circuitry, and not

the hot plug (although there can be interaction). For

example, if the load is a regulator, then the capacitance

may be chosen based on the input requirements of

that circuit (holding regulation under current spikes or

loading, filtering noise, etc.) The value chosen will then

affect how the inrush current is controlled. Note that in

the case of a regulator, there may be capacitors on the

output of that circuit as well; these need to be added

into the capacitance calculation during inrush (unless

the regulator is delayed from operation by the PWRGD

signal, for example).

RL - is the equivalent resistive value of the load; it

determines the normal operation current delivered

through the FET. It also affects some dynamic

conditions (such as the discharge time of the load

capacitors during a power-down). A typical value might

be 48Î© (I = V/R = 48/48 = 1A).

R2, C1, R3, C2 - are related to the gate driver, as it

controls the inrush current.

R2 prevents high frequency oscillations; 10Î© is a

typical value. R2 = 10Î©.

R3 and C2 act as a feedback network to control the

inrush current. I inrush = (Igate*CL)/C2, where CL is

the load capacitance (including module input

capacitance), and Igate is the gate pin charging

current, nominally 45ÂµA. So choose a value of

acceptable inrush for the system, and then solve for

C2. So I = 45ÂµA*(CL/C2). Or C2 = (45ÂµA*CL)/I.

C1 and R3 prevent Q1 from turning on momentarily

when power is first applied. Without them, C2 would

pull the gate of Q1 up to a voltage roughly equal to

VEE*C2/CGS(Q1) (where CGS is the FET gate-source

capacitance) before the ISL6140 could power up and

actively pull the gate low. Place C1 in parallel with the

gate capacitance of Q1; isolate them from C2 by R3.

C1 = (VINMAX - VTH)/VTH*(C2+CGD) where VTH is

the FETâs minimum gate threshold, Vinmax is the

maximum operating input voltage, and Cgd is the FET

gate-drain capacitance.

R3 = (VINMAX + ÎVGATE)/5mA its value is not

Applications: Inrush Current

The primary function of the ISL6140 hot plug controller

is to control the inrush current. When a board is

plugged into a live backplane, the input capacitors of

the boardâs power supply circuit can produce large

current transients as they charge up. This can cause

glitches on the system power supply (which can affect

other boards!), as well as possibly cause some

permanent damage to the power supply.

The key to allowing boards to be inserted into a live

backplane then is to turn on the power to the board in

a controlled manner, usually by limiting the current

allowed to flow through a FET switch, until the input

capacitors are fully charged. At that point, the FET is

fully on, for the smallest voltage drop across it.

In addition to controlling the in-rush current, the

ISL6140 also protects the board against overcurrent,

overvoltage, undervoltage, and can signal when the

output voltage is within its expected range (PWRGD).

Note that although this IC was designed for -48V

systems, it can also be used as a low-side switch for

positive 48V systems; the operation and components

are usually similar. One possible difference is the kind

of level shifting that may be needed to interface logic

signals to the UV input (to reset the latch) or PWRGD

output. For example, many of the IC functions are

referenced to the IC substrate, connected to the VEE

pin. But this pin may be considered -48V or GND,

depending upon the polarity of the system. And input

or output logic (running at 5V or 3.3V or even lower)

might be externally referenced to either VDD or VEE of

the IC, instead of GND.

FN9039.4

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