I
NTEGRATED
C
IRCUITS
D
IVISION
CPC5622
R03 www.ixysic.com 13
Figure 5. Differential and Single-ended Transmit
Path Connections to LITELINK
3.4 Initialization Requirement
Following Power-up
OH must be de-asserted (set logic high) once after
power-up for at least 50ms to transfer internal gain
trim values within LITELINK. This would be normal
operation in most applications. Failure to comply with
this requirement will result in transmission gain errors
and possibly distortion.
3.5 DC Characteristics
The CPC5622 is designed for worldwide applications.
Modification of the values of the components at the
ZDC, DCS1, and DCS2 pins allow for control of the VI
slope characteristics of LITELINK. Selecting
appropriate resistor values for R
ZDC
(R16) and
R
DCS2
(R15) in the provided application circuits
enable compliance with various DC requirements.
3.5.1 Setting a Current Limit
LITELINK includes a telephone line current limit
feature that is selectable by choosing the desired
value for R
ZDC
(R16) using the following formula:
IXYS Integrated Circuits Division recommends using
8.2 for R
ZDC
for most applications, limiting
telephone line current to 130 mA.
Whether using the recommended value above or
when setting R
ZDC
higher for a lower loop current limit
refer to the guidelines for FET thermal management
provided in AN-146, Guidelines for Effective
LITELINK Designs.
3.6 AC Characteristics
3.6.1 Resistive Termination Applications
North American and Japanese telephone line AC
termination requirements are met with a resistive
600 ac 2-wire termination. For these applications
LITELINK’s 2-wire network termination impedance is
set by the resistor R
ZNT
(R10) located at the ZNT pin,
pin 29, with a value of 301.
3.6.2 Reactive Termination Applications
Many countries use a single-pole complex impedance
to model the telephone network transmission line
characteristic impedance as shown in the table below.
Proper gain and termination impedance circuits for a
complex impedance requires the use of complex
network on ZNT as shown in the “Reactive Termination
Application Circuit” on page 8.
3.6.3 Mode Pin Usage
Asserting the MODE pin low (MODE = 0) introduces a
7 dB pad into the transmit path and adds 7 dB of gain
to the receive path. These changes compensate for
the gain changes made to the transmit and receive
paths necessary for reactive termination
implementations. Overall insertion loss with the
reactive termination application circuit and MODE
asserted is 0 dB.
Overall insertion loss with MODE
de-asserted
(MODE
= 1) for the resistive termination application
circuit is 0 dB.
LITELINK
LITELINK
TXA1
TXA2
-
+
0.1μf
0.1μf
Low-Voltage Side CODEC or
Transmit Circuit
Low-Voltage Side CODEC or
Transmit Circuit
TX-
TX+
TXA1
-
+
0.1μf
TX-
TX+
N/C
I
CL
Amps
1V
R
ZDC
------------- 0 . 0 0 8 A+=
Line Impedance Model
Australia China TBR 21
R
S
220 200 270
R
P
820 680 750
C
P
120 nF 100 nF 150 nF
R
S
R
P
C
P