IC-HX_17 Datasheet, PDF(8/14 Page) IC-Haus GmbH – 3-CHANNEL DIFFERENTIAL COLD LINE DRIVER

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IC-HX_17 Datasheet, PDF (8/14 Pages) IC-Haus GmbH – 3-CHANNEL DIFFERENTIAL COLD LINE DRIVER

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iC-HX

3-CHANNEL DIFFERENTIAL COLD LINE DRIVER

DESCRIPTION

Rev D1, Page 8/14

Line drivers for control engineering couple TTL- or

CMOS-compatible digital signals with 24 V systems via

cables. The maximum permissible signal frequency is

dependent on the capacitive load of the outputs (ca-

ble length) or, more specifically, the power dissipation

in iC-HX resulting from this. To avoid possible short

circuiting the drivers are current-limited and shutdown

with excessive temperature.

When the output is open the maximum output voltage

corresponds to supply voltage VB (with the exception

of any saturation voltages). Figure 2 gives the typical

DC output characteristic of a driver as a function of the

load. The differential output resistance is typically 75 â¦

over a wide voltage range.

VB = 40 V

VE = hi

ther reflection of back travelling signals is prevented by

an integrated impedance network, as shown in Figure 3.

T iCâHX Input

iCâHX Output

PCL Input

(100 m line)

vert. 8 V/div hor. 2 Âµs/div

Figure 3: Reflections caused by a mismatched line

termination

During a pulse transmission the amplitude at the iC-

output initially only increases to half the value of sup-

ply voltage VB as the internal driver resistance and

characteristic line impedance form a voltage divider. A

wave with this amplitude is coupled into the line and

experiences after a delay a total reflection at the high-

-impedance end of the line. At this position, the reflected

wave superimposes with the transmitted wave and gen-

erates a signal with the double wave amplitude at the

receiving device.

iCâHX Input T

VB = 24 V

iCâHX Output

100

200

300

400

500

- I(A) [mA]

PLC Input (100 m line)

180 ns

760 ns

vert. 8V/div hor. 500 ns/div

Figure 4: Pulse transmission and transit times

Figure 2: Load dependence of the output voltage

(High-side stage)

Each open-circuited input is set to low by an internal

pull-down current source; an additional connection to

GND increases the deviceâs immunity to interference.

The inputs are TTL- and CMOS-compatible. Due to

their high input voltage range, the inputs can also be

set to high-level by applying VCC or VB.

LINE EFFECTS

In PLC systems data transmission using 24 V sig-

nals usually occurs without a matched line termination.

A mismatched line termination generates reflections

which travel back and forth if there is also no line adap-

tation on the driver side of the device. With rapid pulse

trains transmission is disrupted. In iC-HX, however, fur-

After a further delay, the reflected wave also increases

the driver output to the full voltage swing. iC-HXâs

integrated impedance adapter prevents any further re-

flection and the achieved voltage is maintained along

and at the termination of the line.

A mismatch between iC-HX and the transmission line

influences the level of the signal wave first coupled into

the line, resulting in reflections at the beginning of the

line. The output signal may then have a number of grad-

uations. Voltage peaks beyond VB or below GND are

capped by integrated diodes. By this way, transmission

lines with a characteristic impedance of between 30

and 140 â¦ thus permit correct operation of the device.

iC-xSwitch

Power dissipation in the driver occurs with each switch-

▷