PBL38640-2 Ver la hoja de datos (PDF) - Ericsson
Número de pieza
componentes Descripción
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PBL38640-2 Datasheet PDF : 16 Pages
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PBL 386 40/2
+
TIP
ZL
VTR
ZTR
+
EL
-
-
RING
TIPX
RF RP
RF RP
RINGX
+
RHP
G 2-4S
-
IL
VTX
IL
ZT
+
VTX
-
Four-Wire to Two-Wire Gain
From (1), (2) and (3) with EL = 0:
G4 −2
=
VTR
VRX
=
− ZT
ZRX
⋅
ZT
αRSN
ZL
+ G2 − 4S ⋅ ( ZL
+ 2RF
+ 2RP)
PBL 386 40/2
RSN
I L /αRSN
ZRX
+
VRX
-
Figure 9. Simplified ac transmission circuit.
Functional Description
and Applications Infor-
mation
Transmission
General
A simplified ac model of the transmission
circuits is shown in figure 9. Circuit
analysis yields:
VTR
= VTX
G2 − 4S
+ IL ⋅ (2RF
+ 2RP )
(1)
VTX + VRX = IL
ZT ZRX αRSN
(2)
VTR = EL - IL · ZL
(3)
where:
VTX is a ground referenced version of
the ac metallic voltage between the
TIPX and RINGX terminals.
G2-4S is the programmable SLIC two-wire
to four-wire gain (transmit
direction). See note below.
VTR is the ac metallic voltage between
tip and ring.
EL is the line open circuit ac metallic
voltage.
IL is the ac metallic current.
RF is a fuse resistor.
RP is part of the SLIC protection.
ZL is the line impedance.
ZT determines the SLIC TIPX to
RINGX impedance at voice
frequencies.
ZRX controls four- to two-wire gain.
VRX is the analog ground referenced
receive signal.
αRSN is the receive summing node
current to metallic loop current
gain = 200.
Note that the SLICs two-wire to four-wire
gain, G2-4S, is user programmable
between two fix values. Refer to the
datasheets for values on G2-4S.
Two-Wire Impedance
To calculate ZTR, the impedance pre-
sented to the two-wire line by the SLIC
including the fuse and protection
resistors RF and RP, let:
VRX = 0.
From (1) and (2):
ZTR
=
ZT
αRSN ⋅ G 2− 4S
+
2RF
+
2RP
Thus with ZTR, αRSN, G2-4S, RP and RF
known:
ZT = αRSN ⋅ G2− 4S ⋅ (Z TR − 2RF − 2RP )
Two-Wire to Four-Wire Gain
From (1) and (2) with VRX = 0:
G2− 4
=
VTX
VTR
=
ZT / αRSN
ZT
αRSN ⋅ G2 − 4S
+
2RF
+ 2RP
For applications where
ZT/(αRSN·G2-4S) + 2RF + 2RP is chosen to
be equal to ZL the expression for G4-2
simplifies to:
G4 −2
=−
ZT
ZRX
⋅
1
2G2 − 4S
Four-Wire to Four-Wire Gain
From (1), (2) and (3) with EL = 0:
G4 −4
=
VTX
VRX
=
− ZT
ZRX
⋅
G 2− 4S ⋅ ( ZL + 2RF + 2RP)
ZT
αRSN
+ G2 −4 S ⋅ ( ZL
+ 2RF
+
2RP )
Hybrid Function
The hybrid function can easily be
implemented utilizing the uncommitted
amplifier in conventional CODEC/filter
combinations. Please, refer to figure 10.
Via impedance ZB a current proportional
to VRX is injected into the summing node
of the combination CODEC/filter ampli-
fier. As can be seen from the expression
for the four-wire to four-wire gain a
voltage proportional to VRX is returned to
VTX. This voltage is converted by RTX to a
current flowing into the same summing
node. These currents can be made to
cancel by letting:
VTX
RTX
+
VRX
ZB
= 0(EL
= 0)
The four-wire to four-wire gain, G4-4,
includes the required phase shift and
thus the balance network ZB can be
calculated from:
ZB
=
−RTX
⋅
VRX
VTX
=
R TX
⋅
ZRX
ZT
⋅
ZT
α RSN
+ G2 −4 S ⋅ (ZL
+ 2RF
+ 2RP )
G2 −4 S ⋅ (ZL + 2RF + 2RP )
10
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