ETC TXC-20153-DCMM

DS3LIM-SN
DS3/STS-1 Line Interface Module
NRZ Clock/Data Output
TXC-20153D, TXC-20153G
DATA SHEET
DESCRIPTION
FEATURES
• Complete B3ZS analog to NRZ digital DS3/
STS-1 line interface unit in a compact 2.6
square inch, 50-pin DIP Module
• Single +5V power supply
• Analog inputs and outputs are transformer
coupled
• Meets DSX cross connect frame mask
requirements (ANSI Standard T1.102-1993)
The DS3/STS-1 Line Interface Module (DS3LIM-SN) is
a complete and compact full duplex analog line to digital
terminal interface. It converts B3ZS-encoded line signals, in either DS3 asynchronous or STS-1 synchronous format, to and from NRZ data and clock signals. In
addition to the synchronous signal option, this Module
offers other improvements relative to the TranSwitch
DS3 Line Interface Module (DS3LIM, TXC-20049D),
which it can replace in some existing DS3 applications.
• Full loopback capability
Sensitive analog circuitry meets DS3/STS-1 performance requirements for signal recovery and transmission, with direct line connection via on-board
transformers. Integration of functions into a single Module frees the user from complex printed circuit board
design and testing for the DS3/STS-1 analog section,
reducing the time required for applications development
and product introduction.
• Coding violation and loss of signal detection for
received signal
APPLICATIONS
• TXC-20153D has monitor pin for received signal
input. TXC-20153G has pull-up for external
clock input and improved performance margins.
• DS3/STS-1 interface for quick “time to market”
products
• Adaptive equalization for zero to 900 feet of
cable
• Input dynamic range of 20 dB (100mV - 0.95V)
• Meets DS3/STS-1 jitter requirements of Bellcore
Technical References
• Speeds time to market for prototype
development
• Eases parts inventory and acquisition
• Eases field maintenance
LINE SIDE
TERMINAL SIDE
B3ZS analog input
(from BNC connector)
DS3LIM-SN
TXC-20153D/TXC-20153G
NRZ data and
clock out
B3ZS analog output
(to BNC connector)
DS3/STS-1 Line Interface
Module
NRZ data and
clock in
Status
Coding Violation
U.S. Patent No. 5,119,326
U.S. and/or foreign patents issued or pending
Copyright  1998 TranSwitch Corporation
TranSwitch, TXC and XBERT are registered trademarks of TranSwitch Corporation
Control
External reference clock:
44.736 MHz (DS3)
51.840 MHz (STS-1)
TranSwitch Corporation • 3 Enterprise Drive • Shelton, Connecticut 06484
Tel: 203-929-8810 • Fax: 203-926-9453 • www.transwitch.com
Document Number:
TXC-20153-MB
Ed. 2, August 1998
•
USA
DS3LIM-SN
TXC-20153D, TXC-20153G
TABLE OF CONTENTS
SECTION
PAGE
Product Overview ..................................................................................................4
Block Diagram .......................................................................................................5
Block Diagram Description ....................................................................................5
Pin Diagram ..........................................................................................................7
Pin Descriptions ....................................................................................................7
Absolute Maximum Ratings and Environmental Limitations ................................12
Power Requirements ..........................................................................................12
Input and Output Parameters ..............................................................................13
Timing Characteristics ........................................................................................16
Operation ...................................................................................................... 21-27
Receiver Input Requirements ......................................................................21
Interfering Tone Tolerance ...........................................................................21
Receiver Output Specifications ....................................................................21
Transmitter Specifications ............................................................................22
AIS and Loopback Control Signal Arbitration ...............................................22
Jitter Transfer ...............................................................................................23
Jitter Generation ..........................................................................................23
Jitter Tolerance ............................................................................................ 23
Interference Margin...................................................................................... 25
Physical Design of Motherboard ..................................................................26
Functional Differences Between the DS3LIM-SN and DS3LIM Modules ...........27
Circuit Diagrams ........................................................................................... 29-31
Package Information ...........................................................................................32
Ordering Information ...........................................................................................34
Related Products ................................................................................................34
Standards Documentation Sources .............................................................. 35-36
List of Data Sheet Changes .......................................................................... 37-38
Documentation Update Registration Form * ..................................................41
* Please note that TranSwitch provides documentation for all of its products. Customers who are using
a TranSwitch Product, or planning to do so, should register with the TranSwitch Marketing Department
to receive relevant updated and supplemental documentation as it is issued. They should also contact
the Applications Engineering Department to ensure that they are provided with the latest available information about the product, especially before undertaking development of new designs incorporating
the product.
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
LIST OF FIGURES
Figure 1.
Figure 2.
Figure 3a.
Figure 3b.
Figure 3c.
Figure 3d.
Figure 4.
Figure 5.
Figure 6.
Figure 7a.
Figure 7b.
Figure 7c.
Figure 8.
Figure 9.
Figure 10.
Figure 11.
Figure 12.
Figure 13.
Figure 14.
DS3LIM-SN Block Diagram ...............................................................5
DS3LIM-SN Pin Diagram ...................................................................7
DS3 Interface Isolated Pulse Mask ..................................................16
DS3 Interface Isolated Pulse Mask Equations .................................17
STS-1 Interface Isolated Pulse Mask Equations .............................17
STS-1 Interface Eye Diagram Mask ................................................18
NRZ Transmit Input Timing...............................................................19
NRZ Receive Output Timing ............................................................20
Coding Violation Pulse Timing .........................................................20
DS3LIM-SN Input Jitter Tolerance for DS3 (Category I)...................24
DS3LIM-SN Input Jitter Tolerance for DS3 (Category II)..................24
DS3LIM-SN Input Jitter Tolerance for STS-1 ..................................24
Interference Margin Test Configuration ...........................................25
Power Supply and Ground Connections ..........................................26
DS3LIM-SN Circuit Diagram (TXC-20153D, -20153G Edition 1) .....30
DS3LIM-SN Circuit Diagram (TXC-20153G Edition 2) .....................31
DS3LIM-SN Simplified Outline Drawing ..........................................32
Installation Without Motherboard Socket .........................................33
Installation With Motherboard Socket ..............................................33
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
PRODUCT OVERVIEW
The DS3LIM-SN Module employs TranSwitch’s latest DS3/STS-1 receiver/transmitter VLSI device on a small
printed circuit board assembly with line-coupling transformers and dual-port terminal interface circuits. Use of
the TranSwitch ART VLSI device (Advanced DS3/STS-1 Receiver/Transmitter, TXC-02020) provides improved
performance and reduced cost relative to the TranSwitch DS3LIM Module, which is based on the DS3-only
DS3RT receiver/transmitter VLSI device. In addition to the STS-1 synchronous capability, the ART device has
on-board AGC, equalization and output amplification, functions which had to be provided with external components on the DS3LIM.
The DS3LIM-SN is mechanically compatible with the DS3LIM and is intended to supersede it for both existing
and new applications. The reduced cost and improved performance (wider dynamic range, simultaneous loopback capability) are advantages for existing applications, providing that certain constraints imposed by electrical differences from the DS3LIM can be accommodated (see the section below entitled “Functional
Differences between DS3LIM-SN and DS3LIM Modules”). For new applications the STS-1 capability and single power supply are additional advantages.
Three versions of the DS3LIM-SN Module are available, with two different product numbers and part numbers
(please see the Ordering Information section). The TXC-20153D product is the original version. It provides a
pin (MON, pin 46) for monitoring the received signal input at the 75 ohm terminating resistor on the secondary
side of the input transformer. Since this pin has electrical characteristics different from those of the corresponding pin on the DS3LIM Module, the TXC-20153D may not be suitable for substitution in DS3LIM applications
where this pin is not used for monitoring but has a termination that takes advantage of the superior DS3LIM
output characteristics. The TXC-20153G product was introduced for use in such applications. The first version
of the TXC-20153G (Edition 1) has two layout differences relative to the TXC-20153D: it has no monitor output
connection to pin 46, and it has a pull-up resistor on the external clock input (DCK, pin 27). However, this Edition 1 is less immune to noise than the TXC-20153D. In applications where excessive board noise is present,
and when receiving a signal greater than 800 mV peak, bit errors may occur. Edition 2 of the TXC-20153G was
introduced for use in such applications. It is identical to Edition 1, except for a modification to the receive input
circuit that provides 4 dB attenuation of the input signal at the input to the ART device.
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
BLOCK DIAGRAM
Receive Line
Interface
Receive Terminal
Interface
(TXC-20153G, edition 2, only)
RXLOS
+5VDCR
CV
RGND
RXAIS
SLCT
RXDIS
RC1
RX_B3ZS XFMR
4 dB
Atten.
AGC/
ADAPTIVE
EQUALIZER
P
CLOCK
N
RECOVERY C
B3ZS
DECODER
RX I/O
CONTROL
RX TERMINAL
INTERFACE
MUX
RC2
RD1
RD2
MON
(TXC-20153D only)
TR
LOS
DETECTOR
TRANSWITCH
ART DEVICE
DS3 AIS
GENERATOR
LOOPBACK
CONTROLS
RT
TC1
TX_B3ZS
XFMR
OUTPUT
CONTROL
B3ZS
P ENCODER
N
TX I/O
CONTROL
TX TERMINAL
INTERFACE
MUX
TC2
TD1
TD2
Transmit Line
Interface
TXDIS TXLEV TXAIS
DCK
+5VDCT
TR RT
TGND
Transmit Terminal
Interface
(TXC-20153G only)
Figure 1. DS3LIM-SN Block Diagram
BLOCK DIAGRAM DESCRIPTION
A block diagram for the DS3LIM-SN Module is shown in Figure 1, which is explained below.
In the receive direction, the DS3LIM-SN receives a bipolar B3ZS-encoded DS3 or STS-1 signal from the line
via a BNC or other connector. This signal (RX_B3ZS) is AC-coupled into the DS3LIM-SN through a 1:1 transformer (XFMR). From the transformer, the signal is terminated into a 75 ohm resistance, either as a single 75
ohm shunt resistor or as a 27/47 ohm resistor pair that provides 4 dB attenuation at its junction (in TXC20153G Edition 2 only). The resulting signal is then routed to the input of an Automatic Gain Control (AGC) circuit in the ART device (dotted outline). A Monitor pin (MON) is provided for observing the received signal in the
TXC-20153D only. The AGC provides the Adaptive Equalizer circuit with a constant signal level. The equalizer
is switched in and out to recover narrow or wide width DS3/STS-1 signals, respectively. From the equalizer, the
bipolar signal is connected to the LOS Detector and Clock Recovery blocks. The line signal is monitored for
transitions, and a loss of signal indication is provided on the signal pin labelled RXLOS.
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
The Clock Recovery block requires an external 44.736 MHz (DS3) or 51.840 MHz (STS-1) clock (DCK) with a
stability of ± 200 ppm. The stability of DCK must be increased to ± 20 ppm if the transmit or receive AIS features are used. The average time to recover the clock is approximately 1 ms when the line signal is applied.
The B3ZS (bipolar with 3-zero substitution) line coded data is decoded by the B3ZS Decoder block. Indications
of coding violation errors, other than normal B3ZS coding substitutions, are provided on the signal pin CV. The
decoder detects coding violation errors in the same fashion as the Telecommunication Techniques Corporation’s TBERD model 305 DS3 Analyzer for system test purposes, but some differences may be encountered
when testing with Scientific Atlanta or Wandel and Goltermann equipment. These errors can occur because of
noise and other impairments on the line. The application that uses the DS3LIM-SN can count the CV pulses
over a known time interval to calculate a close estimate for the Bit Error Rate (BER) performance of the line.
The DS3LIM-SN provides the capability to generate and insert a DS3 Alarm Indication Signal (AIS) into the
NRZ receive data signal at the RD1 or RD2 pins. A low placed on the RXAIS pin enables the DS3 AIS insertion
from the DS3 AIS Generator block. This pin may be connected to the receive loss of signal (RXLOS) pin to
generate AIS. The DS3LIM-SN does not provide a corresponding capability for STS-1 operation.
The decoded signal is processed by the Receive I/O Control and Receive Terminal Interface Multiplexer blocks.
Two receive output ports consisting of a clock and data signal are provided. The first receive output port has
pins labelled RC1 and RD1; the second is labelled RC2 and RD2. Only one port can be active at a time. Data
(RD1/RD2) is clocked out of the DS3LIM-SN with respect to the falling edge of the receive clock (RC1/RC2).
The selection of the receive output port is controlled by the state of the select pin (SLCT, high for port 1). The
unused port is forced into a high impedance state. In addition, the two receive ports can both be disabled and
forced into a high impedance state by placing a low on the RXDIS pin.
In the transmit direction, two transmit ports consisting of clock and data are also provided. The first transmit
port has pins labelled TC1 and TD1; the second is labelled TC2 and TD2. Transmit input data (TD1/TD2) is
clocked into the DS3LIM-SN on positive transitions of the clock signal (TC1/TC2). As in the receiver section,
the SLCT pin determines the transmit input port selection (high for port 1).
The transmit input clock and data signals are processed by the Transmit Terminal Interface Multiplexer and
Transmit I/O Control blocks. The incoming data is encoded by the B3ZS encoder. In the B3ZS line code, each
block of three consecutive zeros is removed and replaced by either of two codes that contain bipolar violations.
These replacement codes are B0V and 00V, where B represents a pulse that conforms to the bipolar rule and
V represents a pulse violating the rule. The choice of these codes is made so that an odd number of bipolar
conforming pulses (B) is transmitted between consecutive bipolar violation pulses (V). The encoded data is
connected to the Output Control block, which contains the formatting circuitry to transform the B3ZS-encoded
data into pulses that meet the requirements for the DS3 or STS-1 line rates and a 75-ohm driver for the 1:1 output transformer. This block also provides the capability to transmit a DS3 Alarm Indication Signal (AIS), which
is independent of the transmit data. A low placed on the TXAIS pin enables the transmit DS3 AIS insertion. A
low placed on the TXDIS pin deactivates the transmit output. When TXDIS is set low, the output impedance of
the TX_B3ZS port becomes a high impedance state. The Output Control block contains a feature to adjust the
output signal for cables longer than 50 feet, which is activated by setting the TXLEV pin low.
In addition to the alarms and control signals, the DS3LIM-SN provides two loopback capabilities for testing
transmit and receive loopback via the Loopback Controls block. Transmit-to-Receive (terminal) loopback connects the data path from the Transmit I/O Control block output to the Receive I/O Control block input, and disables the external receiver input. Transmit-to-Receive loopback is activated by placing a low on the TR signal
pin. Receive-to-Transmit (line) loopback connects the receive data output path to the transmit input circuits and
disables the NRZ transmit input. Receive-to-Transmit loopback is activated by placing a low on the RT pin. Terminal and line loopbacks may be applied together, or at the same time as DS3 AIS insertion into the receive or
transmit data output signals, as described under the heading “AIS and Loopback Control Signal Arbitration” in
the Operation section of this Data Sheet.
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
L1
26 RXERR
27 DCK
28 RD2
29 RD1
30 TXAIS
U2
C17
R14
R1/R21
31 RXAIS
R7
R8
R20
C25
32 TXLOC
33 RC1
34 RC2
35 CV
36 RXLOS
37 SLCT
38 RXDIS
39 +5VDCR
40 +5VDCR
41 +5VDCR
42 -5VDCR
43 -5VDCR
44 RGND
45 RGND
46 MON/NC
47 RGND
48 RGND
49 RX_B3ZS
50 RX_B3ZS
PIN DIAGRAM
C1
T1
TXC-02020
C2
C3
C19
R11
TRANSWITCH
T2
U3
R17
C4
L2
C12
U1
CLK8 25
TD2 24
TD1 23
TC2 22
TC1 21
ASEL1 19
TXLEV 20
TR 17
ASEL0 18
RT 16
EQUALIZE 15
+5VDCT 13
EQUALIZE 14
+5VDCT 12
7
TGND
+5VDCT 11
6
TGND
-5VDCT 10
5
TGND
9
4
TGND
8
3
TGND
TXDIS
2
TX_B3ZS
-5VDCT
1
TX_B3ZS
J1
Note: Some pins do not perform the functions suggested by their labels, as explained in the Pin Descriptions section.
Figure 2. DS3LIM-SN Pin Diagram
PIN DESCRIPTIONS
Symbol *
Pin No.
I/O/P **
Type ***
Name/Function
TX_B3ZS
1, 2
O
Analog
Transmit DS3/STS-1 B3ZS Output: These pins are
AC-coupled, B3ZS-encoded DS3 or STS-1 output signals. They may be applied directly to a 75Ω BNC connector. It is recommended that pin 2 should be
connected to the center pin and pin 1 to the shield of the
BNC connector. Under normal operation, this output has
a 75Ω source impedance. When TXDIS is low, this output is placed into a high-impedance disabled condition.
TGND
3, 4, 5, 6, 7
P
TXDIS
8
I
-5VDCT
9, 10
P
Transmit Ground: Ground pin for transmit side circuitry.
TTLp
Transmit Disable: An active low on this pin disables the
DS3 or STS-1 transmitted signal. An external 10kΩ pullup resistor to +5V is required to enable transmission.
Unused: These pins are not connected within the Module, which does not require a -5V power supply. They
may be connected to the -5V power supply in applications originally designed to use the DS3LIM Module.
Otherwise they must be left floating.
* Note:
Symbols used here are the same as for the DS3LIM Module, although there are some pins for which the
function is different or absent in the DS3LIM-SN, as indicated under Name/Function.
** Note: I=Input; O=Output; P=Power
*** Note: See the Input and Output Parameters section below for digital input and output Type definitions.
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Symbol *
Pin No.
I/O/P **
Type ***
Name/Function
+5VDCT
11, 12, 13
P
EQUALIZE
14, 15
--
--
Unused: These pins are not connected within the Module, which does not require a strap for short cable equalization. They may be left open or joined together for
applications originally designed to use the DS3LIM Module.
RT
16
I
TTLp
Receive-To-Transmit Loopback: An active low
enables the receive (line) loopback feature. This loopback connects the receive terminal NRZ data and clock
outputs to the transmit terminal NRZ data and clock
inputs, and disables the NRZ transmit inputs. (See Note
1)
TR
17
I
TTLp
Transmit-To-Receive Loopback: An active low
enables the transmit (terminal) loopback feature. This
loopback connects the B3ZS transmit line outputs to the
B3ZS receive line inputs, and disables the DS3/STS-1
receive line signal input. (See Note 1)
ASEL0
ASEL1
18
19
---
---
Unused: These pins are not connected within the Module, which does not require amplifier gain select bias.
Each may be connected to +5V by a 10kΩ resistor in
applications originally designed to use the DS3LIM Module. Otherwise they must be left floating.
TXLEV
20
I
TTL
Transmit Level: This pin alters the shape of the transmitted pulse to meet ANSI T1.102 pulse mask requirements at the DSX with different cable lengths. The pin
must be pulled high (with a 10kΩ resistor to +5V) for
cables shorter than 50 feet and must be set low for
cables between 50 and 450 feet long. For applications
originally designed to use the DS3LIM Module to meet
ANSI mask requirements with 0-450 feet of cable this pin
is tied low, and the DS3LIM-SN may not operate correctly with short cables. The transmit output mode is
indeterminate if TXLEV is left floating.
TC1
21
I
TTLr
Transmit Input Clock #1: When a high is placed on the
SLCT lead, TC1 is the input pin for the NRZ transmit
clock. This clock has a 50% ± 5% duty cycle.
TC2
22
I
TTLr
Transmit Input Clock #2: When a low is placed on the
SLCT lead, TC2 is the input pin for the NRZ transmit
clock. This clock has a 50% ± 5% duty cycle.
TD1
23
I
TTL
DS3/STS-1 Transmit Input Data Port 1: Data is
clocked in on positive transitions of TC1. This port is
enabled by placing a high on the SLCT lead.
Transmit +5VDC: +5V, ±5% DC power supply for transmit side circuitry.
Note 1: An external 10kΩ pull-up resistor to +5V is required to disable loopback. Setting RT and TR low simultaneously will
enable both line and terminal side loopbacks (see Operation section for additional information on AIS and loopback
control signal arbitration).
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Symbol *
Pin No.
I/O/P **
Type ***
Name/Function
TD2
24
I
TTL
CLK8
25
--
--
Unused: This pin is not connected within the Module,
which does not require an 8 kHz clock input as a time
base for bit error rate measurement. The pin may have
this clock connected in applications originally designed
to use the DS3LIM Module. Otherwise it must be left
floating.
RXERR
26
O
Tied low
Unused: This pin is tied low within the Module to simulate a low receive bit error rate indication for applications
originally designed to use the DS3LIM Module, in which
this pin goes high to indicate a high error rate. This pin
should otherwise be left floating, since the DS3LIM-SN
does not indicate error rate.
DCK
27
I
CMOS
External Clock: An external 44.736 MHz (DS3) or
51.840 MHz (STS-1) clock having a stability of ± 200
ppm (± 20 ppm if the AIS feature is used), and a duty
cycle of 50% ± 5%. If the duty cycle is relaxed, the transmitted mask may not meet pulse mask requirements.
(See Note 4.)
RD2
28
O
TTL4mA
DS3/STS-1 Receive Output Data Port 2: Data is
clocked out on negative transitions of RC2 (see Note 1).
This port is enabled by placing a low on the SLCT lead.
When this port is disabled, by placing a high on SLCT or
a low on the RXDIS control lead, the output goes to a
high impedance state.
RD1
29
O
TTL4mA
DS3/STS-1 Receive Output Data Port 1: Data is
clocked out on negative transitions of RC1 (see Note 1).
This port is enabled by placing a high on the SLCT lead.
When this port is disabled, by placing a low on SLCT or
a low on the RXDIS control lead, the output goes to a
high impedance state.
TXAIS
30
I
TTLp
Transmit AIS: An active low placed on this pin disables
the transmit data input, and causes a DS3 alarm indication signal to be generated and sent as transmitted data
on the TX_B3ZS output when the Module is operating
with DS3 signals. (See Notes 2 and 3.)
DS3/STS-1 Transmit Input Data Port 2: Data is
clocked in on positive transitions of TC2. This port is
enabled by placing a low on the SLCT lead.
Note 1: Data is also clocked out on negative clock transitions in the DS3LIM Module. The Edition 3 Data Sheet for this
Module incorrectly specifies positive transitions in the pin description.
Note 2: An external 10kΩ pull-up resistor to +5V is required to enable data and disable the AIS.
Note 3: DS3 AIS is defined as a valid M-frame with proper subframe structure. The data payload is a 1010 ... sequence
starting with a 1 after each overhead bit. Overhead bits are as follows: F0=0, F1=1, M0=0, M1=1; C-bits are set to
0; X-bits are set to 1; and P-bits are set for valid parity.
Note 4: In the TXC-20153G Module, the DCK input is connected to the Transmit +5VDC supply line via a 10 kΩ pull-up
resistor and its input current characteristics are modified accordingly.
-9-
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Symbol *
Pin No.
I/O/P **
Type ***
Name/Function
RXAIS
31
I
TTLp
Receive AIS: An active low placed on this pin disables
the receive data, input, and causes a DS3 alarm indication signal to be generated and sent on the RD1 or RD2
output pins when the Module is operating with DS3 signals. (See Notes 2 and 3)
TXLOC
32
O
Pulled high Unused: This pin is pulled high within the Module to
simulate an error-free indication for applications originally designed to use the DS3LIM Module, in which this
pin goes low to indicate that the transmit input clock
(TC1, TC2) is stuck high or low. This pin should otherwise be left floating, since the DS3LIM-SN does not indicate loss of clock.
RC1
33
O
CMOS8mA DS3/STS-1 Receive Output Clock Port 1: This port is
enabled by placing a high on the SLCT lead. When this
port is disabled by placing a low on SLCT or a low on the
RXDIS control lead, the output goes to a high impedance state.
RC2
34
O
CMOS8mA DS3/STS-1 Receive Output Clock Port 2: This port is
enabled by placing a low on the SLCT lead. When this
port is disabled by placing a high on SLCT or a low on
the RXDIS control lead, the output goes to a high impedance state.
CV
35
O
CMOS
Coding Violation: A positive pulse having a duration of
one clock cycle is provided on this pin whenever a B3ZS
coding violation occurs.
RXLOS
36
O
CMOS
Receive Loss of Signal: An active low alarm is generated when 175 ± 75 consecutive zeros appear in the
incoming data stream. It is cleared when ones pulse
density is in the range of 28% to 33% (or more than
33%) for 175 ± 75 consecutive pulses.
SLCT
37
I
CMOSr
Select Port 1 or 2: The ports are enabled and disabled
according to the following table:
- 10 -
Select
High
Low
RD1
Enabled
High Z
RC1
Enabled
High Z
TD1
Enabled
Disabled
TC1
Enabled
Disabled
RD2
High Z
Enabled
RC2
High Z
Enabled
TD2
Disabled
Enabled
TC2
Disabled
Enabled
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Symbol *
Pin No.
I/O/P **
Type ***
Name/Function
RXDIS
38
I
CMOSr
Receive Disable Ports 1 and 2: An active low placed
on this pin disables port 1 (RD1 and RC1), and port 2
(RD2 and RC2). The data and clock output signal leads
are forced to a high impedance state. An external 10kΩ
pull-up resistor to +5V is required to enable port 1 and
port 2.
+5VDCR
39, 40, 41
P
Receive +5VDC: +5V, ±5% DC power supply input for
receive side circuitry.
-5VDCR
42, 43
P
Unused: These pins are not connected within the Module, which does not require a -5V power supply. They
may be connected to the -5V power supply in applications originally designed to use the DS3LIM Module.
Otherwise they must be left floating.
RGND
44, 45, 47, 48
P
Receive Ground: Ground pins for receive side circuitry.
MON/NC
46
O/-
Analog/-
For TXC-20153D:
DS3/STS-1 Received Signal Monitor Point: This output is directly tied to the terminating resistor after transformer coupling. Care must be taken to ensure very
short trace lengths to the MON buffer, or oscillation of
the AGC may occur. If a monitor output is not required, it
is suggested that this pin be left open.
For TXC-20153G (Edition 1 and Edition 2):
No Connect: This pin is not connected within the Module, which provides no capability to monitor the received
input signal. This pin may be connected to an external
termination in applications originally designed to use the
DS3LIM Module, but it should otherwise be treated as a
“No Connect” pin and should be left floating.
RX_B3ZS
49, 50
I
Analog
Receive DS3/STS-1 B3ZS Input: These pins are the
AC-coupled B3ZS-encoded DS3 or STS-1 input signal.
They may come directly from a 75Ω ohm BNC connector. If these signals originate from a BNC connector, it is
recommended that the center pin should be connected
to pin 50 and the shield to pin 49.
- 11 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
ABSOLUTE MAXIMUM RATINGS AND ENVIRONMENTAL LIMITATIONS
Parameter
Symbol
+5V supply voltages
VDD
DC input voltage
VIN
Storage temperature range
Min
-0.5
Ambient operating temperature
TA
0
Moisture Exposure Level
ME
5
Relative Humidity, in-circuit
RH
0
Unit
Conditions
+7.0
V
Note 1
V
Note 1
VDD + 0.5
-55
TS
Max
o
150
C
Note 1
oC
70
100
0 ft/min linear airflow
Level
per EIA/JEDEC
JESD22-A112-A
%
Non-condensing.
Note 2.
Notes:
1.
Conditions exceeding the Min or Max values may cause permanent failure. Exposure to conditions near the Min
or Max values for extended periods may impair device reliability.
2.
Pre-assembly storage in non-drypack conditions is not recommended. Please refer to the instructions on the
“CAUTION” label on the drypack bag in which the Modules are supplied.
POWER REQUIREMENTS
Parameter
Min
Typ
Max
Unit
4.75
5.0
5.25
V
IDD
290
mA
VDD = 5.25V
PDD
1.5
W
VDD = 5.25V
VDD
- 12 -
Test Conditions
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
INPUT AND OUTPUT PARAMETERS
Input Parameters for CMOS
Parameter
Min
Typ
Max
Unit
Test Conditions
VIH
VDD - (VDD / 3)
VDD + 0.3
V
VIL
- 0.3
(VDD / 3)
V
IIH
- 10
µA
VDD = 5.25V
IIL
10
µA
VDD = 5.25V
Input
Capacitance
10
pF
Input Parameters For CMOSr
Parameter
Min
Typ
Max
2.0
VIH
VIL
Input leakage current
50
Input capacitance
5.5
Unit
Test Conditions
V
4.75 <VDD < 5.25
0.8
V
4.75 <VDD < 5.25
120
µA
VDD = 5.25
pF
Note: Input has a 100k (nominal) internal pull-up resistor.
Input Parameters For TTL
Parameter
Min
Typ
Max
2.0
VIH
Unit
Test Conditions
V
4.75 <VDD < 5.25
VIL
0.8
V
4.75 <VDD < 5.25
Input leakage current
10
µA
VDD = 5.25
Input capacitance
5.5
pF
Input Parameters for TTLp
Parameter
Min
Typ
Max
Unit
Test Conditions
VIH
2.0
VDD + 0.3
V
VIL
- 0.3
0.8
V
IIH
- 10
µA
VDD = 5.25V
IIL
550
µA
VDD = 5.25V
10
pF
Input
Capacitance
Note: All TTLp inputs have an internal pull-up resistor.
- 13 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Input Parameters For TTLr
Parameter
Min
Typ
Max
2.0
VIH
VIL
Input leakage current
50
Input capacitance
5.5
Unit
Test Conditions
V
4.75 <VDD < 5.25
0.8
V
4.75 <VDD < 5.25
120
µA
VDD = 5.25
pF
Note: Input has a 100k (nominal) internal pull-up resistor.
Output Parameters for CMOS
Parameter
VOH
Min
Typ
Max
Unit
VDD - 0.5
Test Conditions
V
4 mA source
V
4 mA sink
VOL
0.5
IOH
- 4.0
mA
VDD = 4.75V
IOL
4.0
mA
VDD = 4.75V
tRISE
1.7
2.7
4.2
ns
CLOAD = 15 pF
tFALL
1.9
2.8
4.1
ns
CLOAD = 15 pF
Output Parameters For CMOS8mA
Parameter
Min
Typ
Max
VDD - 0.5
VOH
Unit
Test Conditions
V
VDD = 4.75; IOH = -8.0 mA
VDD = 4.75; IOL = 8.0 mA
VOL
0.4
V
IOL
8.0
mA
IOH
-8.0
mA
tRISE
1.3
2.4
3.8
ns
CLOAD = 25 pF
tFALL
1.1
1.8
2.5
ns
CLOAD = 25 pF
Typ
Max
Unit
Output Parameters For TTL4mA
Parameter
VOH
Min
2.4
Test Conditions
V
VDD = 4.75; IOH = -4.0 mA
VDD = 4.75; IOL = 4.0 mA
VOL
0.6
V
IOL
4.0
mA
IOH
-4.0
mA
tRISE
2.8
6.5
9.2
ns
CLOAD = 15 pF
tFALL
1.3
2.3
3.4
ns
CLOAD = 15 pF
- 14 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Receiver Sensitivity
Parameter
Dynamic Range
Min
Typ
100
Max
Unit
950
mVp
Max
Unit
Test Conditions
Input Parameters For Transformer Coupling
Parameter
Min
Return Loss
Typ
- 26
dB
Isolation Voltage
Turns Ratio
Input Impedance
300
Vrms
82.5
ohms
Max
Unit
300
Vrms
82.5
ohms
Test Conditions
DS3: 22.368 MHz; 25oC
STS-1: 25.920 MHz; 25oC
1:1
67.5
75
Output Parameters For Transformer Coupling
Parameter
Min
Typ
Isolation Voltage
Turns Ratio
Test Conditions
1:1
Output Impedance
(TXDIS = 1)
67.5
75
Output Impedance
(TXDIS = 0)
100k
200k
ohms
- 15 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
TIMING CHARACTERISTICS
Detailed timing diagrams for the DS3LIM-SN are illustrated in Figures 3 through 6. All output times are measured with the maximum load capacitance appropriate for the pin type. Timing parameters are measured at
signal levels of (VOH + VOL)/2 for outputs or (VIH + VIL)/2 for inputs.
Line Side Timing Characteristics
The line side signal characteristics are designed so that the output meets the requirements of ANSI standard
T1.102-1993. When terminated into a test load of 75Ω ± 5% using ATT 734A coaxial cable the DS3LIM-SN
Module will meet the DS3 or STS-1 interface isolated pulse masks defined below in Figures 3a through 3c for
a cable length of 0 to 450 feet. For STS-1 pulse sequences, the output also meets the STS-1 interface eye diagram mask shown in Figure 3d.
1.0
NORMALIZED
AMPLITUDE
0.8
0.6
0.4
MAXIMUM*
0.2
MINIMUM*
0
-0.8
-0.4
0.0
+0.4
+0.8
+1.2
+1.6
TIME, T, IN UNIT INTERVALS (UI)**
* Note: The DS3 curves shown are approximate representations of the equations in Figure 3b. The corresponding
STS-1 curves (not shown) would be slightly different, as indicated by the equations in Figure 3c.
**Note: UI = 1 / (System Clock Frequency)
Figure 3a. DS3 Interface Isolated Pulse Mask
- 16 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
CURVE
MAXIMUM
(UPPER)
CURVE
MINIMUM
(LOWER)
CURVE
NORMALIZED
AMPLITUDE
TIME IN
UNIT INTERVALS
-0.85 < T < -0.68
-0.68 < T < 0.36
0.36 < T < 1.4
0.03
π
T
0.5 1+ sin 2 (1+
)
0.34 +0.03
0.08 + 0.407e -1.84(T-0.36)
[
]
- 0.03
π
0.5 1+ sin 2 (1+
-0.85 < T < -0.36
[
-0.36 < T < 0.36
0.36 < T < 1.4
]
T
)
0.18 - 0.03
- 0.03
Figure 3b. DS3 Interface Isolated Pulse Mask Equations
CURVE
MAXIMUM
(UPPER)
CURVE
MINIMUM
(LOWER)
CURVE
NORMALIZED
AMPLITUDE
TIME IN
UNIT INTERVALS
-0.85 < T < -0.68
-0.68 < T < 0.26
0.26 < T < 1.4
0.03
π
T
0.5 1+ sin 2 (1+
)
0.34 +0.03
0.1 + 0.61e -2.4(T-0.26)
-0.85 < T < -0.38
-0.38 < T < 0.36
0.36 < T < 1.4
[
]
- 0.03
π
0.5 1+ sin 2 (1+
[
]
T
)
0.18 - 0.03
- 0.03
Figure 3c. STS-1 Interface Isolated Pulse Mask Equations
- 17 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
1
D
C
B
0.75
E
L
K
M
NORMALIZED AMPLITUDE
0.5
F
G
J
A
H
0.25
I
N
O
0
-0.25
-0.5
-0.75
-1
-0.5
-0.25
0
0.5
0.25
TIME IN UNIT INTERVALS (UI) *
*Note: UI = 1 / (System Clock Frequency)
Outer region corner points
Inner region corner points
Point
Time
Amplitude
Point
Time
Amplitude
A
-0.5
0.426
I
-0.245
0.214
B
-0.261
0.904
J
-0.187
0.455
C
-0.136
1.03
K
-0.104
0.67
D
-0.028
1.03
L
-0.017
0.67
E
0.094
0.883
M
0.077
0.581
F
0.187
0.723
N
0.18
0.14
G
0.31
0.566
O
-0.054
0.16
H
0.5
0.426
Note - Both inner and outer regions are symmetric about zero amplitude axis.
Figure 3d. STS-1 Interface Eye Diagram Mask
- 18 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Terminal Side Timing Characteristics
Figure 4. NRZ Transmit Input Timing
tPWH
tCYC
TC1,TC2
(Input)
1.4V
tSU
TD1,TD2
(Input)
DATA
VALID
Parameter
tH
DATA
VALID
Symbol
DATA
VALID
Min
Typ
Max
Unit
TC1, TC2 DS3 input clock period
tCYC
22.353
ns
TC1, TC2 STS-1 input clock period
tCYC
19.290
ns
TC1, TC2 high time
tPWH
10
--
45
TD1, TD2 set-up time to TC1↑, TC2↑
tSU
4.0
ns
TD1, TD2 hold time after TC1↑, TC2↑
tH
3.0
ns
TC1, TC2 duty cycle (tPWH/tCYC)
ns
55
%
Note: TC1, TC2 symmetry is measured about the 1.4VDC threshold in order to assure symmetric output waveforms.
- 19 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Figure 5. NRZ Receive Output Timing
tCYC
tPWH
RC1,RC2
(Output)
tOD(1)
RD1,RD2
(Output)
tOD(2)
CV
(Output)
Parameter
Symbol
Min
Typ
Max
Unit
RC1, RC2 DS3 output clock period
tCYC
22.353
ns
RC1, RC2 STS-1 output clock period
tCYC
19.290
ns
RC1, RC2 high time
tPWH
10
--
45
55
%
RD1, RD2 output delay after RC1↓, RC2↓
(RXAIS = 1)
tOD(1)
1.0
5.5
ns
RD1, RD2 output delay after RC1↓, RC2↓
(RXAIS = 0)
tOD(1)
1.0
6.5
ns
CV output delay after RC1↓, RC2↓
tOD(2)
1.0
5.5
ns
RC1, RC2 duty cycle (tPWH/tCYC)
ns
Note: RC1, RC2 symmetry is measured about the 50% amplitude point.
Figure 6. Coding Violation Pulse Timing
tPWH
tPW
CV
(Output)
Parameter
Symbol
Min
Typ
Max
Unit*
CV pulse width
tPW
0.9
1.0
1.1
UI
CV pulse high time
tPWH
0.8
0.9
1.0
UI
CV delay from occurrence of violation
tD
7.0
UI
*Note: UI = 1 / (System Clock Frequency)
- 20 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
OPERATION
Receiver Input Requirements
Parameter
Value
Interface Cable
AT&T 728A/734A coaxial (or equivalent)
Bit Rate:
DS3
44.736 Mbit/s ± 20 ppm
STS-1
51.840 Mbit/s ± 20 ppm
Line Code
B3ZS
Input Signal Amplitude:
100 mVp - 0.95 Vp AC (differential input)
Cable Length
0 - 900 feet
Input Return Loss:
DS3
> 26 dB at 22.368 MHz with external 75Ω resistor
STS-1
> 26 dB at 25.920 MHz with external 75Ω resistor
Input Resistance
> 5kΩ
Signal-to-Noise Tolerance
No greater than either the value produced by adjacent pulses in the data stream
or ±10% of the peak pulse amplitude, whichever is greater.
Input Jitter Tolerance
As defined by Figures 7a, 7b and 7c: “Input Jitter Tolerance”*
*Note: Refer to the Operation - Jitter Tolerance subsection below for DS3 and STS-1 minimum requirements and measured
values.
Interfering Tone Tolerance
The DS3LIM-SN will properly recover clock and present error-free output to the receive terminal side interface*
in the presence of a sinusoidal interfering tone signal at the following line rates:
Interfering Tone Tolerance
Data Rate (Mbit/s)
Tone Frequency (MHz)
Maximum Tone Level
51.84
25.97
-20 dB
44.736
22.4
-20 dB
*Note: See Figure 8: “Interference Margin Test Configuration”
Receiver Output Specifications
Parameter
Value
Clock Recovery Jitter
Peaking
1 dB maximum
Clock Recovery PLL
pull-in time
< 100 µS
Sequences Reported
as Coding Violations
++, --, not B0V, not 00V, three or more consecutive zeros (excessive zeros)
- 21 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Transmitter Specifications
Note: A 75Ω ±5% output load is assumed in these specifications. Measurements made at transmitter unless
otherwise noted.
Parameter
Value
TX_B3ZS Output Charac- The two pulse shapes specified below are to be measured at the end of 50teristics, TXLEV low:
450 feet of cable, terminated by a 75Ω resistor.
Pulse Shape (DS3)
As defined by Figure 2 in ANSI TI.404-1994
Pulse Shape (STS-1)
As defined by Figure 4-10 in GR-253-CORE, Issue 2, December 1995
Amplitude
±0.81 Volts ±10% for DS3; +0.95 for STS-1
Output jitter
0.05 UI maximum with jitter-free input clock on TC1, TC2
TX_B3ZS Output Charac- The two pulse shapes specified below are to be measured at the end of 0-50
teristics, TXLEV high:
feet of cable, terminated by a 75Ω resistor.
Pulse Shape (DS3)
As defined by Figure 2 in ANSI TI.404-1994
Pulse Shape (STS-1)
As defined by Figure 4-10 in GR-253-CORE, Issue 2, December 1995
Amplitude
±0.67 Volts ±10% for DS3; +0.8 for STS-1
Output jitter
0.05 UI maximum with jitter-free input clock on TC1, TC2
*Note: UI = 1 / (System Clock Frequency)
AIS and Loopback Control Signal Arbitration
The response of the Module to combinations of the RXAIS, TXAIS, RT and TR input signals is tabulated
below:
RXAIS *
TXAIS *
RT (line)
TR (term.)
Terminal Output
Line Output
1
1
1
1
Normal
Normal
1
0
X
1
Normal
AIS
1
0
X
0
Term Loopback
AIS
0
1
1
X
AIS
Normal
0
1
0
X
AIS
Line Loopback
0
0
X
X
AIS
AIS
1
1
1
0
Term Loopback
Normal
1
1
0
1
Normal
Line Loopback
1
1
0
0
Term Loopback
Line Loopback
Note: X = Don’t Care
* These signals may only be applied (active low) when the Module is operating with DS3 signals.
- 22 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Jitter Transfer
Transfer of jitter through an individual unit of digital equipment is characterized by the relationship between the
applied input jitter and the resulting output jitter as a function of frequency.
For DS3, Bellcore Technical Reference GR-499-CORE, Issue 1, December 1995 further describes and defines
jitter transfer.
For STS-1, Bellcore Technical Reference GR-253-CORE, Issue 2, December 1995 further describes and
defines jitter transfer.
In a looped back configuration (through the receive path and externally looped back through the transmit path),
in the absence of applied input jitter the amount of jitter introduced by the DS3LIM-SN is maximum 0.065 Unit
Intervals (UIs, where UI is 1 / System Clock Frequency) of peak-to-peak jitter over a jitter frequency range of
20 Hz to 1 MHz (filter with high-pass of 10 Hz and a low-pass of 1.1 MHz).
With applied input jitter, the maximum output jitter is the applied input jitter plus the above jitter introduced by
the DS3LIM-SN.
Jitter Generation
Jitter generation is the process whereby jitter appears at the output port of an individual unit of digital equipment in the absence of applied input jitter.
For DS3, Bellcore Technical Reference GR-499-CORE, Issue 1, December 1995 specifies the maximum jitter
generation to be 1.0 UI of peak-to-peak at the output of the terminal receiver for Category I equipment.
For STS-1, Bellcore Technical Reference GR-253-CORE, Issue 2, December 1995 specifies the maximum jitter generation to be 1.5 UI peak-to-peak maximum at the output of the terminal receiver for Category I equipment.
In a looped back configuration (through the transmit path and externally looped back through the receive path),
the DS3/STS-1 jitter generation within the DS3LIM-SN is 0.145 UI peak-to-peak maximum for all frequencies
specified in these two standards.
Jitter Tolerance
DS3:
Input jitter tolerance is the maximum amplitude of sinusoidal jitter at a given jitter frequency, which, when modulating the signal at an equipment port, results in no more than two errored seconds cumulative, where these
errored seconds are integrated over successive 30-second measurement intervals, and the jitter amplitude is
increased in each succeeding measurement interval.
Requirements for input jitter tolerance are specified in terms of compliance with a jitter mask, which represents
a combination of points. Each point corresponds to minimum amplitude of sinusoidal jitter at a given jitter frequency which, when modulating the signal at an equipment input port, results in two or fewer errored seconds
in a 30-second measurement interval. Bellcore Technical Reference GR-499-CORE, Issue 1, December 1995
specifies the minimum requirement mask for Category I and Category II equipment, which are shown in Figures 7a and 7b.
Jitter tolerance within the DS3LIM-SN meets and exceeds the performance requirements. Figures 7a and 7b
present the Bellcore DS3 minimum jitter tolerance requirement masks for Category I and Category II, respectively, and show the measured performance of the DS3LIM-SN, which exceeds both requirements.
STS-1:
For STS-1, jitter tolerance is specified in Bellcore Technical Reference GR-253-CORE, Issue 2, December
1995. The minimum requirement mask is shown in Figure 7c.
- 23 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Jitter tolerance within the DS3LIM-SN meets and exceeds performance requirements. Figure 7c presents the
Bellcore STS-1 minimum jitter tolerance requirement mask and the measured STS-1 performance of the
DS3LIM-SN.
20
Measured*
50 kHz
-20 dB/decade
5
Sinusoidal Input
Jitter Amplitude
(UI, Peak-Peak,
Log Scale)
* 20 UI is the maximum
measurement limit of
the test equipment.
Minimum
Required
0.1
Note: UI = 22.35 ns
10
2.3k
60k
Jitter
Frequency
(Hz, Log Scale)
300k
Figure 7a. DS3LIM-SN Input Jitter Tolerance for DS3 (Category I)
20
Measured*
10
-20 dB/decade
50 kHz
-20 dB/decade
Sinusoidal Input
Jitter Amplitude
(UI, Peak-Peak,
Log Scale)
Minimum
Required
0.3
* 20 UI is the maximum
measurement limit of
the test equipment.
Note: UI = 22.35 ns
10
2.3k
22.3k
Jitter
Frequency
(Hz, Log Scale)
300k
Figure 7b. DS3LIM-SN Input Jitter Tolerance for DS3 (Category II)
20
15
Measured*
50 kHz
Sinusoidal Input
Jitter Amplitude
(UI, Peak-Peak,
Log Scale)
1.5
Minimum
Required
Note: UI = 19.29 ns
* 20 UI is the maximum
measurement limit of
the test equipment.
0.15
30
300
2k
20k
Jitter Frequency
(Hz, Log Scale)
Figure 7c. DS3LIM-SN Input Jitter Tolerance for STS-1
- 24 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Interference Margin
The interference margin of the DS3LIM-SN is measured using the test configuration shown in Figure 8.
Wavetek 166
Sine Wave
Rate ƒ1/2
Attenuator
Passive
Combiner
RX Out
RX In
DS3LIM-SN
TX Out
HP3784A Test Set
215-1 Pattern
Rate ƒ1
Line out
TX In
Line in
Note: Wavetek generator is set for same pk-pk voltage as test pattern at 0 dB attenuator setting.
ƒ1, MHz
44.736
VCC, V
Min attenuation for no errors, dB
DS3
4.75 - 5.25
20
STS-1
51.84
4.75
20
Signal
Figure 8. Interference Margin Test Configuration
- 25 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Physical Design of Motherboard
High-frequency design techniques must be employed for layout of the printed circuit board on which the
DS3LIM-SN Module is mounted. The following guidelines and suggestions should be adhered to for a successful board design. At the DS3 and STS-1 frequencies it is important to use high-frequency layout techniques. The techniques discussed below are the bare minimum set that should be used.
A solid ground plane should be used. ‘Solid’ in this instance means that the impedance from any point in the
plane to the board ground connection should be low. This is very important in regards to the location of the
analog DS3LIM-SN device since its SNR can be severely degraded by I*Z drops in these planes. Under no
circumstances should a DS3LIM-SN ground pin be connected to ground through a trace. The trace has a finite
impedance at high frequencies; it is not a short. Ground currents through the trace impedance will cause voltage
noise.
Do not use a solid power plane. Break the +5V power plane into regions as shown in Figure 9. Additionally, there
should be a +5V region for board logic. Use as wide a path as possible back to the common connecting point.
If the power and ground planes are placed in adjacent layers there will be an additional noise reduction due to
capacitive coupling. For example, a six-layer board could be signal-signal-power(ground)-ground(power)signal-signal.
BNC
Connector
GROUND
10µF
+5VDCT
+
0.1µF
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
TX_B3ZS
TX_B3ZS
TGND
TGND
TGND
TGND
TGND
TXDIS
-5VDCT
-5VDCT
+5VDCT
+5VDCT
+5VDCT
EQUALIZE
EQUALIZE
RT
TR
ASEL0
ASEL1
TXLEV
TC1
TC2
TD1
TD2
CLK8
RX_B3ZS
RX_B3ZS
RGND
RGND
MON
RGND
RGND
-5VDCR
-5VDCR
+5VDCR
+5VDCR
+5VDCR
RXDIS
SLCT
RXLOS
CV
RC2
RC1
TXLOC
RXAIS
TXAIS
RD1
RD2
DCK
RXERR
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
BNC
Connector
GROUND
0.1µF
+
10µF
+5VDCR
Figure 9. Power Supply and Ground Connections
For the input and output signal connections of the DS3LIM-SN Module a board trace at high frequencies is not
a zero-impedance metal interconnection. It is a distributed L/C network. The values of the L and C parasitic
components are determined by trace geometry (width and height) and the surrounding material. Component
layout should be arranged to permit the use of short traces, especially for the analog inputs. These input traces
should be restricted to one side of the motherboard, since vias have been found to cause degraded performance due to output signal coupling. A trace with a given geometry will have a different impedance if it is on an
- 26 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
outside board layer from the same trace placed instead in an internal layer. Large branches off a main trace
will change the impedance at the branch point due to the effect of impedances in parallel, so branch lengths
should be kept to a minimum (less than a quarter wavelength). This is very important for clock lines where
load/source impedance mismatches can cause severe ringing, which leads to timing problems. Use clock buffers to reduce the difficulty of distributing a clock with many loads.
If relays are used to switch the transceivers in and out, use the 50 ohm shielded variety to minimize crosstalk,
especially from the power used to energize the relay. Match the impedance of the board traces of the transmitter outputs and receiver inputs to the transmission line impedance (75 ohms if a 1:1 transformer is used) to
minimize reflections, and do not use vias in these signal paths. Physically separate the analog signal lines
from the digital lines. Route the differential receiver lines side by side to make coupled noise common-mode.
Avoid ninety-degree corners in the board lands; keep lands as straight and short as possible. Use terminating
(i.e., 51 ohm series-damping) resistors in the digital signals lines where appropriate (i.e., if the line is longer
than a quarter wavelength of the highest signal frequency of importance, reflections will start causing problems).
The above comments are guidelines only. High-frequency board layout is difficult and must be done with care.
A bad board layout will reduce the SNR of the transceiver and cause timing problems with the board logic, perhaps to the point of requiring a complete board redesign.
FUNCTIONAL DIFFERENCES BETWEEN THE DS3LIM-SN AND DS3LIM MODULES
The following nine functional differences between the DS3LIM-SN and DS3LIM Modules affect the utilization
of the pins of the Module. The first two of these differences do not affect the ability of the DS3LIM-SN to be
used as a direct replacement for the DS3LIM. The others represent performance differences which may
require special accommodation by the user.
1. Equalization (Pins 14, 15)
The DS3LIM requires provision of a strap between the two EQUALIZE input pins (14, 15) for line input
cable lengths less than 200 feet. Due to incorporation of the ART VLSI device, which has adaptive equalization, the DS3LIM-SN can provide equalization for all line input cable lengths from zero to 900 feet automatically, without any such special settings based on cable length. The EQUALIZE pins are unused in the
DS3LIM-SN.
2. Amplifier Gain Select (Pins 18, 19)
The DS3LIM requires external pull-up resistors connected to the ASEL0 and ASEL1 input pins (18, 19) for
line input amplifier gain selection. Due to its use of the ART device the DS3LIM-SN has AGC and does not
use these two pins.
3. -5V Power Supply (Pins 9, 10, 42, 43)
The DS3LIM-SN does not require the -5V power supply used by the DS3LIM. The four -5V power input
pins (9, 10, 42, 43) are unused. However, the +5V power supply current requirement of the Module
increases from 200 mA for the DS3LIM to 290 mA for the DS3LIM-SN.
4. TXLEV Input (Pin 20, Transmit Level select for DS3LIM)
The DS3LIM can meet line output pulse mask requirements for all cable lengths from zero to 450 feet with
the TXLEV input (pin 20) set low. With TXLEV set high or left floating a higher transmit level is provided,
which may permit satisfactory performance with longer cables. For the DS3LIM-SN the TXLEV input must
be set according to cable length: low for cable lengths from 50 to 450 feet and high (10kΩ resistor to +5V)
for cables shorter than 50 feet. There is no special provision for cables longer than 450 feet.
For cable lengths from 50 to 450 feet (TXLEV low) the DS3LIM-SN is compatible with the DS3LIM. For
cables shorter than 50 feet the low TXLEV setting provided for the DS3LIM is not suitable, and TXLEV
- 27 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
must be changed to high. For cables longer than 450 feet the DS3LIM-SN may not be able to match the
DS3LIM output pulse performance with TXLEV set high even if TXLEV is changed to low.
Unlike the DS3LIM, the TXLEV pin has no pull-up resistor in the DS3LIM-SN, so the pin does not pull high
if it is left floating and the transmit output mode selection is indeterminate. It is necessary for the pin to be
driven either high or low by an external connection.
5. RXERR Output (Pins 25 and 26, Receive Error Rate for DS3LIM)
The DS3LIM-SN indicates B3ZS coding violations like the DS3LIM, but it does not measure bit error rates
using an 8 kHz clock input (CLK8, pin 25), and it cannot indicate error rates above 10-6, which the DS3LIM
does by setting the RXERR output (pin 26) high. (Note: The Edition 3 Data Sheet for the DS3LIM incorrectly describes this as an active low signal, RXERR.)
The DS3LIM-SN has the CLK8 pin internally disconnected and the RXERR pin internally tied low to simulate an error-free condition at all times, so that it can be used in place of the DS3LIM, but it will not report
bit error rates that exceed the 10-6 threshold. The bit error rate may be calculated externally in the user’s
application, based on monitoring of the coding violation pulses that are provided as the CV output (pin 35)
of the DS3LIM-SN.
6. Loopback Capability (Pins 16, 17)
The DS3LIM Module suffers data corruption at the terminal and line interfaces if the line (RT, pin 16) and
terminal (TR, pin 17) loopback features are selected simultaneously. The DS3LIM-SN exhibits the
extended loopback capabilities of the ART VLSI device, as described in the Operation section of this Data
Sheet, and is not subject to data corruption with simultaneous loopbacks.
The implementation of extended loopback capabilities in the ART VLSI device required the use of internal
loopback path configurations different from those in the DS3RT VLSI device of the DS3LIM. The different
path used for terminal loopback results in a requirement for user application accommodations in treatment
of the RXLOS and CV output signals when the DS3LIM-SN is substituted for the DS3LIM, as described
below.
The DS3LIM implements terminal loopback (Transmit-to-Receive (TR) loopback) close to the line side
inputs and outputs within its DS3RT receiver/transmitter VLSI device. When TR loopback is active, the
RXLOS and CV output signals are driven by the looped-back transmit input signal and will usually indicate
normal operation (i.e., no receive loss of signal or coding violations).
The DS3LIM-SN implements terminal loopback close to the terminal side inputs and outputs within its ART
receiver/transmitter VLSI device. When TR loopback is active, the receive input path connection through to
the receive output is disabled, but the RXLOS and CV output signals are still driven by the receive input
signal. If there is no valid input signal, or the receive input is disconnected during TR loopback so that
there is noise pickup, the RXLOS and CV output signals will reflect this indeterminate receive input condition rather than the looped-back transmit input signal. Spurious receive loss of signal and coding violation
indications may result. The user application should either disregard the RXLOS and CV outputs during TR
loopback or arrange to apply a valid signal to the receive input so that these outputs do not become active.
7. TXLOC Output (Pin 32, Transmit Loss of Clock for DS3LIM)
The DS3LIM-SN does not have the capability to detect and indicate when the transmit input clock (TC1,
TC2) is stuck high or low, which the DS3LIM does by setting the TXLOC output pin (32) low.
The DS3LIM-SN has the TXLOC pin internally pulled up to simulate an error-free condition at all times, so
that it can be used in place of the DS3LIM but will not report a loss of clock condition.
- 28 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
8. Receive Loss of Signal Modified (RXLOS, pin 36)
The DS3LIM detects and indicates receive loss of signal when a positive or negative data transition does
not occur for 128 or more clock cycles. Recovery occurs on the first positive or negative transition.
The DS3LIM-SN detects and indicates receive loss of signal when 175 ± 75 zeroes appear in the incoming
data stream. Recovery occurs when the ones pulse density is in the range of 28% to 33% (or more than
33%) for 175 ± 75 consecutive pulses.
9. Receive Signal Monitor Output (MON, pin 46)
The TXC-20153D version of the DS3LIM-SN is more sensitive to external loading of this output pin than is
the DS3LIM Module. The TXC-20153G version does not have a monitor output connection to pin 46.
10. Digital Input and Output Parameter Type Changes (Pins Listed Below)
The pins listed below have different Types of input or output parameter in the DS3LIM-SN and the DS3LIM.
Electrical parameter definitions for these Types are provided in the Input and Output Parameters Section of
this Data Sheet.
Symbol
Pin No.
I/O
Parameter Type
DS3LIM-SN
DS3LIM
TXDIS
8
I
TTLp
CMOS or TTL
RT
16
I
TTLp
CMOSr
TR
17
I
TTLp
CMOSr
DCK
27
I
CMOS(1)
TTL
TXAIS
30
I
TTLp
TTLr
RXAIS
31
I
TTLp
CMOSr
CV
35
O
CMOS
TTL2mA
RXLOS
36
O
CMOS
TTL2mA
TXLEV(2)
20
I
TTL
CMOSr
Notes:
1. A 10 kΩ pull-up resistor is provided in the TXC-20153G Module only.
2. No pull-up resistor is provided in the DS3LIM-SN Modules.
CIRCUIT DIAGRAMS
The circuit diagram for the TXC-20153D and TXC-20153G Edition 1 versions of the DS3LIM-SN Module is provided in Figure 10. Note 1 of this figure indicates the differences between the TXC-20153D and TXC-20153G
versions. The resistors marked X are not installed, since the Module has the NRZ interface. Figure 11 shows
the corresponding circuit diagram for the TXC-20153G Edition 2, which provides 4 dB attenuation at the
receive line input. Both circuit diagrams are reduced versions of larger drawings, so the annotation text is
unavoidably small. Enlarged versions of the diagrams may be viewed or printed from the PDF file version of
this Data Sheet on the TranSwitch World Wide Web Site (www.transwitch.com) using Acrobat Reader software.
The Reader can zoom portions of the diagram for viewing. A zoomed area may then be selected with Tools/
Select Graphics and Edit/Copy to move it via the clipboard to any word processor (Edit/Paste) for printing.
- 29 -
TXC-20153-MB
Ed. 2, August 1998
U1 Power and Ground Pins
VDD GND
FUNCTION
DATA REC
30
33
CLK REC (A)
28
29
CLK REC (D)
25
24
RX OUT
17
12
RX/TX DIG
10
11
C9
C10
C11
C12
C13
VCCT
C21
CAP01-10UF
CAP00-.1UF
CAP00-.1UF
CAP00-.1UF
CAP00-.1UF
CAP00-.1UF
VCCT
L2
50MHZ_EMI_FIL
VCCR
VCCR
C15
C14
CAP01-10UF
CAP00-.1UF
CAP00-.1UF
TX OUT CNTL
6,5
4,3
PLL
34
36
RGND
RGND
TX OUT
37
39
TGND
TGND
1
VCCR
C18
CAP00-.1UF
CAP01-10UF
- 30 -
S-FERRITE
2
VCCR1
L3
C3
C22
CAP01-10UF
CAP01-10UF
C20
CAP00-.1UF
C19
RGND29
VCCR30
31
32
RGND33
34
35
RGND36
VCCT 37
38
TGND39
CAP00-.01UF
T26
CAP01-10UF
C5
TXC-20153-MB
Ed. 2, August 1998
NOTE 1:
TXC-20153-GCMM
Disconnect Mon Pin
Do Install: R19 (10K)
TXC-20153-DCMM
Mon Pin Connected
Do not Install: R19 (10K)
J1B
50 RXD1 (RX_B3ZS)
49 RXD2 (RX_B3ZS)
48 RGND (RGND)
47 RGND (RGND)
46 MON (MON/NC)
45 RGND (RGND)
44 RGND (RGND)
43 "NC" (-5VDCR)
42 "NC" (-5VDCR)
41 +5VDCR (+5VDCR)
40 +5VDCR (+5VDCR)
39 +5VDCR (+5VDCR)
38 RXDIS- (RXDIS_)
37 SLCT (SLCT)
36 RXLOS- (RXLOS_)
35 BPV (CV)
34 RC2 (RC2)
33 RC1 (RC1)
32 TXLOC- (TXLOC_)
31 RXAIS- (RXAIS_)
30 TXAIS- (TXAIS_)
29 RD1 (RD1)
28 RD2 (RD2)
27 DCK (DCK)
26 RXERR (RXERR)
M-HDR25
L1
50MHZ_EMI_FIL
1
IND C IND 3
A
P
2
VCCR
Note: Symbols in parenthesis correspond to
pin symbols used in Data Sheet, but with suffix _
replacing symbol overline.
VCCT
C7
R19
RES01-10K
(SEE NOTE 1)
R6
RD2
RES01-51
CAP00-.1UF
RR
XX
LA
I B
DO
SP
CS
K- - V
R10
RD1
RES01-51
22222222211
U1
87654321098
A NN A A B B R DR C
V CC V G3 I E L A V
D
D NZ S F OI
D
D DS T C S S
R
R RD K
X
X XI
VCCT
S
DVDD 17
AGNDRX
16
RP/RD 15
AVDDRX
RN 14
DI1
CLKO 13
DI2
CLKO 12
AGNDRX
TGND
DGND11
AVDDTPLL
TGND
DGND10
TPLLC
VCCT
DVDD 9
AGNDTPLL
TP/TD 8
AVDDTX
TN
DOUT
CLKI 7
AGNDTX
A AA A
D R
S Z L T GGV V
X Z T T NR N ND D
DE X A L L D DD D
NI R I I B B T T T T
CS ON S K K X X X X
44444123456
01234
TXC-02020-AIPL
44-PIN ART
T Z T RT T T V V
X E X T RGGCC
DR A - - NN CC
DD T T
I O I
S- S
-
1
2
3
4
5
6
7
8
9
10
11
TGND12
U2
24
BE VCC 23
C0
D4 22
A0
B4 21
B0
A4 20
D0
C4 19
C1
D3 18
A1
B3 17
B1
A3 16
D1
C3 15
C2
D2 14
A2
B2
GND BX 13
SQS3383Q
RES01-0
R17
Y
Y
R15
RES01-75
R14
RES01-0
R11
RES01-0
RES01-51
R8
RC2
RC1
VCCT
R7
RES01-51
TGND 1
TC1 2
3
4
TC2 5
TD1 6
7
8
TD2 9
10
11
TGND 12
U3
24
BE VCC 23
C0
D4 22
A0
B4 21
B0
A4 20
D0
C4 19
C1
D3 18
A1
B3 17
B1
A3 16
D1
C3 15
C2
D2 14
A2
B2
GND BX 13
SQS3383Q
NRZ MODE
Install: R15
Do Not Install: R11,R14
R17,R18
Figure 10. DS3LIM-SN Circuit Diagram (TXC-20153D, TXC-20153G Edition 1)
R9
RES01-4.7K
SLCT
VCCT
C6
CAP00-.1UF
DS3LIM-SN
TXC-20153D, TXC-20153G
4
TXD1 3
S-WB1010
C4
CAP00-.01UF
VCCT
C23
CAP00-.1UF
RXERR
TGND
TXLOCRXDIS-
VCCT
VR
CG
CN
RD
R1
RES01-75
CAP00-.01UF
14
13
12
11
10
9
8
IND C IND 3
A
P
2
DCK
CAP00-.01UF
C2
U4
1A VCC
6A
1Y
6Y
2A
5A
2Y
5Y
3A
4A
3Y
GND 4Y
S74HCT04
R18
RES01-75
C1
RXD1 1 T1 6
TXD2 1
ZERO 1
ZERO- 2
TGND 3
4
TGND 5
6
TGND 7
S-FERRITE
2
C17
L4
MON
4
RXD2 3
S-WB1010
VCCT 1
C16
J1A
TXD1 (TX_B3ZS) 1
TXD2 (TX_B3ZS) 2
TGND (TGND)
3
4
TGND (TGND)
5
TGND (TGND)
6
TGND (TGND)
7
TGND (TGND)
8
TXDIS- (TXDIS_)
9
"NC" (-5VDCT)
10
"NC" (-5VDCT)
+5VDCT (+5VDCT) 11
+5VDCT (+5VDCT) 12
+5VDCT (+5VDCT) 13
"NC" (EQUALIZE) 14
"NC" (EQUALIZE) 15
16
RT- (RT_)
17
TR- (TR_)
18
"NC" (ASEL0)
19
"NC" (ASEL1)
ZERO (TXLEV) 20
TC1 (TC1) 21
TC2 (TC2) 22
TD1 (TD1) 23
TD2 (TD2) 24
"NC" (CLK8) 25
M-HDR25
- 31 -
DS3LIM-SN
TXC-20153D, TXC-20153G
TXC-20153-MB
Ed. 2, August 1998
Figure 11. DS3LIM-SN Circuit Diagram (TXC-20153G Edition 2)
DS3LIM-SN
TXC-20153D, TXC-20153G
PACKAGE INFORMATION
The DS3/STS-1 Line Interface Module consists of a 2.6 x 1.0 inch multi-layer printed circuit board with surface
mounted components on both sides and 50 signal/power pins at 0.1 inch spacing on the two long edges to provide a DIP configuration. Figure 12 is a simplified drawing that shows three views of the Module. All dimensions are in inches and are nominal unless otherwise indicated.
2.600 ± 0.005
C13
R15
C21
U4
C11
C23
C9
C14
1.000 ± 0.005
L3
C6
R9
C7
C5
0.900 ± 0.020
(See Note 4)
C20
R1 9
R18
R6
R10
C16
C18
L4
C10
C22
C15
0.100 ± 0.010
0.210
MAX
0.120 MAX
0.300
0.062 ± 0.005
R20
C25
R7
R8
U2
R14
C17
C1
T1
TXC-02020-AIPL
C2
T2
C4
C3
C19
TRANSWITCH
TOP VIEW
R21
L1
R11
R17
U3
L2
C12
U1
J1
Notes:
1. Module is shown approximately twice full size.
2. All dimensions are in inches, and are nominal unless otherwise indicated.
3. R11, R14, R17 and R18 are not installed. R19 (10 kΩ) is a coaxial-lead resistor.
4. The axis of each pin is located within ± 0.010 inch vertically and ± 0.005 inch horizontally from its
nominal position.
5. This figure shows the component layout for TXC-20153G Edition 2 (also refer to Figure 11).
6. The component layout for TXC-20153D and TXC-20153G Edition 1 has C25 and R20 removed,
and R21 replaced by R1 (refer to Figure 10).
Figure 12. DS3LIM-SN Simplified Outline Drawing
- 32 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
The DS3LIM-SN can be installed without or with a socket on the motherboard, as shown in Figures 13 and 14,
respectively. All dimensions are shown in inches and are nominal unless otherwise indicated.
0.060
0.250
Connector (one pin of 25-pin strip)
SAMTEC, Inc. #BBL-125-T-E, see Note 3
Module
XFMR
or
Indctr.
0.108
Module PC Board
Module
Indctr.
0.070
0.120 MAX
0.125
Motherboard PC Board
0.060
Pin 0.018 DIA
Figure 13. Installation Without Motherboard Socket
SAMTEC Module Connector #BBL-125-T-E mates with SAMTEC Micro-socket #SL-125-TT-19 or SL-125-TT-39 (LIF)
Flanges 0.07 DIA
0.060
0.250
Module
XFMR
#BBL-125-T-E (one pin of 25-pin strip)
Module PC Board
Module
0.120 MAX Indctr.
0.070
0.153
0.083
0.165
Motherboard PC Board
0.060
Hollow leg 0.029 DIA
Socket on Motherboard (one of 25-socket strip)
SAMTEC. Inc. #SL-125-TT-19 or SL-125-TT-39 (LIF), see Note 3
Figure 14. Installation With Motherboard Socket
Notes For Figures 13 and 14:
1. All dimensions are in inches and are nominal unless otherwise indicated.
2. Drawings not to scale.
3. SAMTEC, Inc.
P.O. Box 1147
New Albany, Indiana 47151-1147 USA
Phone: 812-944-6733
Fax: 812-948-5047
TWX: 810-540-4095
Telex: 333-918
- 33 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
ORDERING INFORMATION
Product Number: TXC-20153D
Part Number: TXC-20153-DCMM DS3/STS-1 Line Interface Module, NRZ Clock/Data Output
50-Pin Dual In-Line Package
Monitor pin provided for receive line signal input, no DCK pull-up
Product Number: TXC-20153G
Part Number: TXC-20153-GCMM DS3/STS-1 Line Interface Module, NRZ Clock/Data Output
50-Pin Dual In-Line Package
No monitor pin, pull-up provided for DCK external clock input)
Edition 1:
0 dB attenuation provided for receive line input
Edition 2:
4 dB attenuation provided for receive line input
RELATED PRODUCTS
TXC-20049D, DS3LIM Module (DS3 Line Interface Module). A complete analog to digital
converter which receives and transmits B3ZS-encoded DS3 line signals and provides serial
NRZ clock and data interfaces on the terminal side.
TXC-21049, DS3LIM Evaluation Board. A complete, ready-to-use test bed for the test and
evaluation of the DSLIM-SN and DS3LIM Line Interface Modules. The Module plugs into a
socket on the evaluation board, input and output signals are terminated via BNC connectors,
and all functions of the Module are selectable via jumper insertion/extraction on the evaluation
board.
TXC-20163, E3LIM Module (E3 Line Interface Module). A complete and compact full duplex
analog line to digital terminal interface that converts an HDB3-encoded line signal, in E3
asynchronous format, to and from NRZ data and clock signals. The E3LIM is packaged as a
2.6 inch x 1.0 inch 50-pin Dual In-Line Package (DIP) Module.
TXC-02020, ART VLSI Device (Advanced DS3/STS-1 Receiver/Transmitter). Performs the
receive and transmit line interface functions required for transmission of DS3 (44.736 Mbit/s) or
STS-1 (51.840 Mbit/s) signals across a coaxial interface. The TXC-02021 ARTE device has
some extended features relative to the ART and has a different package with more pins to
support additional input and output signals.
TXC-03303, M13E VLSI Device. This single-chip multiplex/demultiplex device provides the
complete interfacing function between a single DS3 signal and 28 independent DS1 signals.
TXC-03401B, DS3F VLSI Device (DS3 Framer). Maps broadband payloads into the DS3 frame
format. Operates in either the C-bit parity or M13 operating modes.
TXC-06125, XBERT VLSI Device (Bit Error Rate Generator Receiver). Programmable multirate test pattern generator and receiver in a single chip with serial, nibble, or byte interface
capability.
- 34 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
STANDARDS DOCUMENTATION SOURCES
Telecommunication technical standards and reference documentation may be obtained
from the following organizations:
ANSI (U.S.A.):
American National Standards Institute (ANSI)
11 West 42nd Street
New York, New York 10036
Tel: 212-642-4900
Fax: 212-302-1286
The ATM Forum (U.S.A.):
ATM Forum World Headquarters
303 Vintage Park Drive
Foster City, CA 94404-1138
ATM Forum European Office
14 Place Marie - Jeanne Bassot
Levallois Perret Cedex
92593 Paris France
Tel: 415-578-6860
Fax: 415-525-0182
Tel: 33 1 46 39 56 26
Fax: 33 1 46 39 56 99
Bellcore (U.S.A.):
Bellcore
Attention - Customer Service
8 Corporate Place
Piscataway, NJ 08854
Tel: 800-521-CORE (In U.S.A.)
Tel: 908-699-5800
Fax: 908-336-2559
EIA - Electronic Industries Association (U.S.A.):
Global Engineering Documents
Suite 407
7730 Carondelet Avenue
Clayton, MO 63105
Tel: 800-854-7179 (In U.S.A.)
Fax: 314-726-6418
ETSI (Europe):
European Telecommunications Standards Institute
ETSI, 06921 Sophia - Antipolis
Cedex France
Tel: 33 92 94 42 00
Fax: 33 93 65 47 16
ITU-T (International):
Publication Services of International Telecommunication Union (ITU)
Telecommunication Standardization Sector (T)
Place des Nations
CH 1211
Geneve 20, Switzerland
Tel: 41-22-730-5285
Fax: 41-22-730-5991
- 35 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
TC (Japan):
TTC Standard Publishing Group of the
Telecommunications Technology Committee
2nd Floor, Hamamatsucho - Suzuki Building,
1 2-11, Hamamatsu-cho, Minato-ku, Tokyo
Tel: 81-3-3432-1551
Fax: 81-3-3432-1553
- 36 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
LIST OF DATA SHEET CHANGES
This change list identifies those areas within this updated DS3LIM-SN Data Sheet that have significant differences relative to the previous and now superseded DS3LIM-SN Data Sheet:
Updated DS3LIM-SN Data Sheet:
Ed. 2, August 1998
Previous DS3LIM-SN Data Sheet:
Ed. 1A, November 1996
The page numbers indicated below of this updated Data Sheet include significant changes relative to the previous data sheet. Please note that repagination changes and changes of Figure numbers are not listed.
Page Number of
Updated Data Sheet
All
1, 40, 42
Summary of the Change
Changed edition number and date.
Changed TranSwitch street address in Shelton, CT.
1
In Features list, changed features five and six.
2-3
Updated Table of Contents and List of Figures.
4
Changed third paragraph.
5
In Figure 1, added 4 dB Attenuator block after receive line input transformer. Changed second paragraph.
7
Added C25, R20 and R21 to Figure 2.
11
Added “Edition 1 and Edition 2” to Name/Function column for pin 46.
12
Changed first table and moved ambient operating temperature row from
second table to first table.
14
Deleted Output Parameters For TTL2mA table (no pins of this type).
Changed last table
15
Changed first table.
16
Changed first paragraph.
21
Changed Value column for Input Signal Amplitude, Cable Length and Input
Jitter Tolerance in first table. Changed Maximum Tone Level column for
both rows in second table.
22
Changed Values for Pulse Shape (DS3) and Pulse Shape (STS-1) in first
table. Changed Parameter and Value in last row of first table.
23
Updated Bellcore Technical Reference numbers in 6 locations.
Added references to Category 1 equipment and associated new Figure 7a.
24
Added Figure 7a. Changed titles of Figures 7b and 7c.
25
Changed last column of table in Figure 8.
26
Changed second and third paragraphs of Physical Design of Motherboard.
Changed RGROUND and TGROUND to GROUND in Figure 9.
27
Changed 450 feet to 900 feet in “1. Equalization (pins 14,15)” subsection.
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TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
Page Number of
Updated Data Sheet
Summary of the Change
29
Changed last paragraph.
30
Changed title of Figure 10.
31
Added Figure 11.
32
Changed Top View and added notes 5 and 6 of Figure 12.
34
Changed Ordering Information to describe the three versions of the
DS3LIM-SN Module that can be ordered. Updated Related Products.
35
Updated Standards Documentation Sources, adding EIA.
37-38
41
Substituted new List of Data Sheet Changes.
Updated Documentation Update Registration Form.
- 38 -
TXC-20153-MB
Ed. 2, August 1998
DS3LIM-SN
TXC-20153D, TXC-20153G
- Notes-
TranSwitch reserves the right to make changes to the product(s) or
circuit(s) described herein without notice. No liability is assumed as a
result of their use or application. TranSwitch assumes no liability for
TranSwitch applications assistance, customer product design, software performance, or infringement of patents or services described
herein. Nor does TranSwitch warrant or represent that any license,
either express or implied, is granted under any patent right, copyright,
mask work right, or other intellectual property right of TranSwitch covering or relating to any combination, machine, or process in which
such semiconductor products or services might be or are used.
- 39 -
TXC-20153-MB
Ed. 2, August 1998
Engines for Global Connectivity
TranSwitch Corporation
•
3 Enterprise Drive
•
Shelton, CT 06484 USA
- 40 -
•
Tel: 203-929-8810
•
Fax: 203-926-9453
•
www.transwitch.com
DS3LIM-SN
TXC-20153D, TXC-20153G
DOCUMENTATION UPDATE REGISTRATION FORM
If you would like be added to our database of customers who have registered to receive updated documentation
for this device as it becomes available, please provide your name and address below, and fax or mail this page
to Mary Lombardo at TranSwitch. Mary will ensure that relevant Product Information Sheets, Data Sheets,
Application Notes, Technical Bulletins and other relevant publications are sent to you. This information will be
made available in paper document form, on a Windows/DOS/Macintosh/UNIX CD-ROM disk, and on the
Internet World Wide Web at the TranSwitch site, http://www.transwitch.com.
Please print or type the information requested below, or attach a business card.
Name: ________________________________________________________________________
Title: _________________________________________________________________________
Company: _____________________________________________________________________
Dept./Mailstop: ________________________________________________________________
Street: _______________________________________________________________________
City/State/Zip: _________________________________________________________________
If located outside U.S.A., please add - Postal Code:
___________ Country: ______________
Telephone:______________________________________________ Ext.: _________________
Fax: __________________________________
E-Mail: _______________________________
Purchasing Dept. Location: _______________________________________________________
Check a box if your computer has a CD-ROM drive: DOS ‰ Windows ‰ Mac ‰
Check box if you have Internet Web access: ‰
↓
UNIX ‰
Sun ‰ Solaris ‰ HP ‰ Other ‰
Please describe briefly your intended application for this device, and indicate whether you would
care to have a TranSwitch applications engineer contact you to provide assistance:
______________________________________________________________________________
______________________________________________________________________________
______________________________________________________________________________
______________________________________________________________________________
______________________________________________________________________________
If you are also interested in receiving updated documentation for other TranSwitch device types,
please list them below rather than submitting separate registration forms:
__________
__________
__________
__________
__________
__________
Please fax this page to Mary Lombardo at (203) 926-9453 or fold, tape and mail it (see other side).
- 41 -
TXC-20153-MB
Ed. 2, August 1998
Engines for Global Connectivity
(Fold back on this line second, then tape closed, stamp and mail.)
First
Class
Postage
Required
TranSwitch Corporation
Attention: Mary Lombardo
3 Enterprise Drive
Shelton, CT 06484
U.S.A.
(Fold back on this line first.)
Please complete the registration form on this back cover sheet, and fax or mail it, if you
wish to receive updated documentation on this TranSwitch product as it becomes available.
TranSwitch Corporation
•
3 Enterprise Drive
•
Shelton, CT 06484 USA
•
Tel: 203-929-8810
•
Fax: 203-926-9453
•
www.transwitch.com