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HCPL4200 Datasheet, PDF (10/12 Pages) Agilent(Hewlett-Packard) – Optically Coupled 20 mA Current Loop Receiver
Figure 17. Simplex Current Loop System Configurations for (a) Point-to-Point, (b) Multidrop.
and OFF states. This non-isolated
active transmitter provides a
nominal 20 mA loop current for
the listed values of VCC, R2 and
R3 in Figure 18.
Length of current loop (one
direction) versus minimum
required DC supply voltage, VCC,
of the circuit in Figure 18 is
graphically illustrated in Figure
19. Multidrop configurations will
require larger VCC than Figure 19
predicts in order to account for
additional station terminal
voltage drops.
Typical data rate performance
versus distance is illustrated in
Figure 20 for the combination of
a non-isolated active transmitter
and HCPL-4200 optically coupled
current loop receiver shown in
Figure 18. Curves are shown for
10% and 25% distortion data
rate. 10% (25%) distortion data
rate is defined as that rate at
which 10% (25%) distortion
occurs to output bit interval with
respect to input bit interval. An
input Non-Return-to-Zero (NRZ)
test waveform of 16 bits
(0000001011111101) was used
for data rate distortion measure-
ments. Data rate is independent
of current source supply voltage,
VCC.
The cable used contained five
pairs of unshielded, twisted, 22
AWG wire (Dearborn #862205).
Loop current is 20 mA nominal.
Input and output logic supply
voltages are 5 V dc.
Full Duplex
The full duplex point-to-point
communication of Figure 21 uses
a four wire system to provide
simultaneous, bidirectional data
communication between local and
remote equipment. The basic
application uses two simplex
point-to-point loops which have
two separate, active, non-isolated
units at one common end of the
loops. The other end of each loop
is isolated.
As Figure 21 illustrates, the
combination of Hewlett-Packard
current loop optocouplers, HCPL-
4100 transmitter and HCPL-4200
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