Analog Devices AN694 Application Notes

AN-694

–

–

APPLICATION NOTE

One Technology Way • P.O. Box 9106 • Norwood, MA 02062-9106 • Tel: 781/329-4700 • Fax: 781/326-8703 • www.analog.com

Hot Swap and Blocking FET Control Using 2 ⴛ ADM1073 Hot Swap Controllers

by Alan Moloney

INTRODUCTION

In many –48 V hot swap systems, there is a blocking diode in
series with the hot swapping FET. This component ensures
that current can only fl ow into the load in one direction, pre­venting damage to the board in the case of reverse currents
fl owing. Figure 1 shows this implementation in an ADM1073
controlled system.

This solution can have serious power dissipation impli­cations during normal operation due to the voltage drop
across the blocking diode

PPP P

=+ +

LOSS FET DIODE QUIESCENT

where

P Load Current Diode Voltage Drop

=

DIODE

Note that P
tion

of the total power loss (see Figure 1).

()

will be r e s p onsibl e for a substantial

DIODE

×

()

por-

This is especially evident in applications where the aver­age load current level is high and the total power losses
are calculated across an entire system, which may
con

sist of multiple racks of boards.

PLUG-IN BOARD

48VRTN

As explained in this application note, another solution
for systems where this power loss is unacceptable is to
replace the blocking diode with a blocking FET that
a low on resistance. A second ADM1073 can con

has

trol
this blocking FET. Figure 2 shows this solution on a
plug-in board.

This solution will reduce the power dissipation during
operation to

PP P P

=++

LOSS HSWAP-FET BLK -FET QUIESCENT

where

P Load Current FET On Resistance

Note that P

BLK-FET

=

()

will be much smaller than P

BLK-FET

2

×

()

and

DIODE

will therefore reduce the total power loss signifi cantly.

The AN-694 Application Note should be consulted in
conjunction with the ADM1073 data sheet.

PLUG-IN BOARD

48VRTN

LIVE
BACKPLANE

(ADM1073)

BLOCKING

FET

CONTROLLER

(ADM1073)

HOT SWAP

FET

CONTROLLER

LOAD

LIVE
BACKPLANE

–48V

(ADM1073)

HOT SWAP

FET

CONTROLLER

HOT SWAP

R

SENSE

SERIES BLOCKING DIODE

FET

LOAD

–48V

BLOCKING

FET

R

HOT SWAP

SENSE

SERIES BLOCKING FET REPLACES DIODE

FET

Figure 2. Alternative Solution—Blocking FET
Replaces Diode

Figure 1. Blocking Diode in Series with Hot Swap FET

REV. 0

AN-694

–48VRTN

–48VIN

800k⍀

R9
500k⍀

R8

R10
250k⍀

OV

UV

SS

t

V

ON

V

EE

R1
30k⍀

IN

SUPPLYGOOD

LATCHEDOFF

SOFTRESEAT

ADM1073(B)

SENSE

GATE DRAIN

PWRGD

RESET

FET2

Figure 3. Full Implementation of Dual ADM1073 Solution for Blocking FET and Hot Swap FET Control

DETAILED DESCRIPTION

Figure 3 shows a full implementation of a dual ADM1073
solution for blocking FET and hot swap FET control.

FET1 is the hot swap FET. This device must also have a
low on resistance and a high reverse voltage capabil­ity. This device will be required to dissipate high power
during startup, so a D2PAK device may be required.
ADM1073(A) is the hot swap FET controller that con­trols FET1.

FET2 is the blocking FET. This device must have a low
on resistance to minimize power dissipation and a high
reverse voltage capability. This device will not have to
dissipate as much power so a smaller package may be
suitable (e.g., SOIC). ADM1073(B) is the blocking FET
controller that controls FET2.

A single sense element, R

, can be used for both

SENSE

ADM1073 devices. With this method, the ADM1073(A)
will limit forward load current to 100 mV/R

SENSE

the ADM1073(B) will limit reverse load current to
18 mV/100 mV.

Example Confi guration for ADM1073(A)

The undervoltage level is set by R5 and R6. R5 = 500 k;
R6 = 15 k will normally give a UV rising threshold of

32.3 V and a UV falling threshold of 29.8 V. In this case,
the UV rising level will actually be 32.9 V + FET1 body
diode voltage drop (~1 V) and UV falling level will be

29.8 V + I

2

R of FET2.

The overvoltage level is set by R3 and R4. R3 = 400 k;
R4 = 10 k will normally give an OV rising threshold
of 79.1 V and an OV falling threshold of 77.1 V. In this
case, the OV falling level will actually be 77.1 V + FET2
body diode voltage drop (~1 V) and the OV rising level
will be 79.1 V + I

2

R of FET1.

R2
30k⍀

V

IN

R3

R4

R5
500k⍀

R6
15k⍀

R

SENSE

0.010⍀

C

SS

2.2nF
C

t

82nF

OV

UV

SS

t

ON

ON

V

EE

400k⍀

10k⍀

The soft start time is set by C3. C3 = 2.2 nF = > tSS =

The tON time is selected by the CtON capacitor, e.g., CtON =
gives a t

rain fold back (for FET SOA protection) is set with

The d

of 5.8 ms at –48 V.

ON (MAX)

SUPPLYGOOD

LATCHEDOFF

SOFTRESEAT

ADM1073(A)

SENSE

GATE DRAIN

PWRGD

RESET

FET1

R

DRAIN

5M⍀

LOAD

0.9 ms.

82 nF

R7.

A 5 M resistor will be suffi cient to charge a 470 F load.

The dropper resistor R2 is set to 30 k for normal opera

tion.

The LATCHEDOFF o u t p ut is t ied bac k to the SO FTRESEAT
input to give a continuous retry with a 5 second cooling
off period under short- circuit condition.

The RESET input is used as the start-up control if it is
required.

The PWRGD output is used as a hot swap completion
fl ag, which is required.

The SUPPLYGOOD output is connected to the OV pin of the
ADM1073(B) to provide a start-up signal to the ADM1073(B)
based on the voltage detection in the ADM1073(A).

;

Example Confi guration for ADM1073(B)

The SENSE and V

pins connect across the ADM1073(A)

EE

sense resistor with connections reversed, i.e., the
ADM1073(B) SENSE pin is connected to the ADM1073(A)
V

pin and the ADM1073(B) VEE pin is connected to

EE

the ADM1073(A) SENSE pin. This will configure the
ADM1073(B) to regulate current in FET2 only if it sees a
reverse current fl owing in the sense resistor.

The Undervoltage (UV) pin is tied to a resistor divider
from the VIN pin. The resistor values should be chosen

so
that the voltage on the UV pin is always above the UV
threshold, e.g., R9 = 500 k; R10 = 250 k = > VUV = 4

The Overvoltage (OV) pin is connected to the SUP

V.

PLY-

GOOD output of the ADM1073(A) so that startup of the

–2–

REV. 0