VND810 Datasheet VND810, VND81013TR | P16-P18

Application information VND810

16/27

3 Application information

Figure 24. Application schematic

3.1 GND protection network against reverse battery

This section provides two solutions for implementing a ground protection network against

reverse battery.

3.1.1 Solution 1: a resistor in the ground line (R

GND

only)

This can be used with any type of load.

The following show how to dimension the R

GND

resistor:

1. R

GND

≤ 600mV / 2 (I

S(on)max

)

2. R

GND

≥ ( - V

) / ( - I

GND

)

where - I

GND

is the DC reverse ground pin current and can be found in the absolute

maximum rating section of the device datasheet.

Power dissipation in R

GND

(when V

< 0 during reverse battery situations) is:

= ( - V

)

/ R

GND

This resistor can be shared amongst several different HSDs. Please note that the value of

this resistor should be calculated with formula (1) where I

S(on)max

becomes the sum of the

maximum on-state currents of the different devices.

OUTPUT2

+5V

prot

OUTPUT1

STATUS1

INPUT1

+5V

STATUS2

INPUT2

GND

+5V

prot

GND

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VND810 Application information

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Please note that, if the microprocessor ground is not shared by the device ground, then the

GND

will produce a shift (I

S(on)max

* R

GND

) in the input thresholds and the status output

values. This shift will vary depending on how many devices are ON in the case of several

high-side drivers sharing the same R

GND

If the calculated power dissipation requires the use of a large resistor, or several devices

have to share the same resistor, then ST suggests using solution 2 below.

3.1.2 Solution 2: a diode (D

GND

) in the ground line

A resistor (R

GND

= 1kΩ) should be inserted in parallel to D

GND

if the device will be driving

an inductive load. This small signal diode can be safely shared amongst several different

HSD. Also in this case, the presence of the ground network will produce a shift (j600mV) in

the input threshold and the status output values if the microprocessor ground is not common

with the device ground. This shift will not vary if more than one HSD shares the same

diode/resistor network. Series resistor in INPUT and STATUS lines are also required to

prevent that, during battery voltage transient, the current exceeds the Absolute Maximum

Rating. Safest configuration for unused INPUT and STATUS pin is to leave them

unconnected.

3.2 Load dump protection

is necessary (voltage transient suppressor) if the load dump peak voltage exceeds the

maximum DC rating. The same applies if the device is subject to transients on the V

line that are greater than those shown in the ISO T/R 7637/1 table.

3.3 MCU I/O protection

If a ground protection network is used and negative transients are present on the V

line,

the control pins will be pulled negative. ST suggests to insert a resistor (R

prot

) in line to

prevent the µC I/O pins from latching up.

The value of these resistors is a compromise between the leakage current of µC and the

current required by the HSD I/Os (Input levels compatibility) with the latch-up limit of µC

I/Os:

- V

CCpeak

/ I

latchup

≤ R

prot

≤ (V

OHµC

- V

GND

) / I

IHmax

Example

For the following conditions:

CCpeak

= - 100V

latchup

≥ 20mA

OHµC

≥ 4.5V

5kΩ ≤ R

prot

≤ 65kΩ.

Recommended values are:

prot

= 10kΩ

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Application information VND810

18/27

3.4 Open load detection in off-state

Off-state open load detection requires an external pull-up resistor (R

) connected between

OUTPUT pin and a positive supply voltage (V

) like the +5V line used to supply the

microprocessor.

The external resistor has to be selected according to the following requirements:

1) no false open load indication when load is connected: in this case we have to avoid V

OUT

to be higher than V

Olmin

; this results in the following condition

OUT

= (V

/ (R

+ R

))R

< V

Olmin.

2) no misdetection when load is disconnected: in this case the V

OUT

has to be higher than

OLmax

; this results in the following condition R

< (V

- V

OLmax

) / I

L(off2)

Because I

s(OFF)

may significantly increase if V

out

is pulled high (up to several mA), the pull-

up resistor R

should be connected to a supply that is switched OFF when the module is in

standby.

Figure 25. Open load detection in off-state

V batt. V

DRIVER

LOGIC

IN P U T

STATUS

OUT

GROUND

L(off2)

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