EXAR XRT82D20

áç
XRT82D20
SINGLE CHANNEL E1 LINE INTERFACE UNIT
APRIL 2001
REV. 1.0.7
GENERAL DESCRIPTION
The XRT82D20 is a fully integrated, single channel,
Line Interface Unit (Transceiver) for 75 Ω or 120 Ω E1
(2.048 Mbps) applications. The LIU consists of a
receiver with adaptive data slicer for accurate data
and clock recovery and a transmitter which accepts
either single or dual-rail digital inputs for signal
transmission to the line using a low- impedance
differential line driver. The LIU also includes a crystalless jitter attenuator for clock and data smoothing
which, depending on system requirements, can be
selected in either the transmit or receive path.
Coupling the XRT82D20 to the line requires transformers on both the Receiver and Transmitter sides,
and supports both 120 Ω balanced and 75 Ω unbalanced interfaces. The receiver can be capacitive
coupled to for cost reduction
• Clock Recovery and Selectable Crystal-less Jitter
attenuator
• Compliant with ETS300166 Return Loss
• Compliant with the ITU-T G.823 Jitter Tolerance
Requirements
• Remote, Local and Digital Loop backs
• Declares and Clears LOS per ITU-T G.775
• Logic Inputs accept either 3.3V or 5.0V levels
• - 400C to 850C Temperature Range
• Low Power Dissipation; 145mW with 120 Ω or
160mW with 75 Ω typical
• +3.3V or +5V Supply Operation
• Pin Compatible with the XRT7288
APPLICATIONS
• PDH Multiplexers
FEATURES
• Complete E1 (CEPT) line interface unit
• SDH Multiplexers
• Generates transmit output pulses that are compliant with the ITU-T G.703 Pulse Template for
2.048Mbps (E1) rates
• DECT (Digital European Cordless Telephone) Base
Stations
• On-Chip Pulse Shaping for both 75 Ω and 120 Ω
Line Drivers
• Test Equipment
• Digital Cross-Connect Systems
• CSU/DSU Equipment
FIGURE 1. BLOCK DIAGRAM OF THE XRT82D20
TClk
TPOS
TNEG
TTIP
HDB3
Encoder
Tx Pulse
Shaper
MUX
TRing
Jitter Attenuator
Digital
Loopback
RClk
RPOS
RNEG
Line
Driver
HDB3
Decoder
Remote
Loopback
Local
Loopback
LOS
Detect
Data &
Timing
Recovery
MUX
Timing
Generator
Data
Slicer
RLOS
Peak
Detector
RTIP
RRing
MClk
Exar Corporation 48720 Kato Road, Fremont CA, 94538 • (510) 668-7000 • FAX (510) 668-7017 • www.exar.com
áç
SINGLE CHANNEL E1 LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
FIGURE 2. PINOUT OF THE XRT82D20
RLOS
1
28
RTIP
ClkLOS
2
27
RRing
TNEG/CODE
3
26
MuteRx
RNEG/LCV
4
25
AGND
RClk
5
24
AVDD
RPOS/RData
6
23
TxLEV
TClk
7
22
TTIP
TPOS/TData
8
21
TVDD
LLoop
9
20
TRing
RLoop
10
19
TGND
DLoop
11
18
JAEN
ATM
12
17
DIGI
RAOS
13
16
JATx/Rx
TAOS
14
15
MClk
ORDERING INFORMATION
PART #
PACKAGE
OPERATING TEMPERATURE RANGE
XRT82D20IW
28 Lead 300 Mil Jedec SOJ
-40oC to + 85oC
2
XRT82D20
SINGLE CHANNEL E1 LINE INTERFACE UNIT
áç
REV. 1.0.7
TABLE OF CONTENTS
GENERAL DESCRIPTION ................................................................................................. 1
FEATURES ................................................................................................................................................
APPLICATIONS .........................................................................................................................................
Figure 1. Block Diagram of the XRT82D20 ..................................................................................................
Figure 2. Pinout of the XRT82D20 ................................................................................................................
ORDERING INFORMATION ..............................................................................................................................
1
1
1
2
2
PIN DESCRIPTIONS .......................................................................................................... 3
Figure 3. Interface Timing Diagram in Both Single-Rail and Dual-Rail Mode, with DIGI (Pin 17) = “0” . 5
Figure 4. Interface Timing Diagram in Dual-Rail Mode only, with DIGI (Pin 17) = “1” ............................. 6
ELECTRICAL CHARACTERISTICS .................................................................................. 7
TABLE 1: RECEIVER CHARACTERISTICS .............................................................................................................. 7
TABLE 2: TRANSMITTER CHARACTERISTICS ........................................................................................................ 7
TABLE 3: 3.3V POWER CONSUMPTION INCLUDING LINE POWER DISSIPATION, TRANSMISSION AND RECEIVE PATHS
ALL ACTIVE ........................................................................................................................................................ 7
TABLE 4: 5V POWER CONSUMPTION INCLUDING LINE POWER DISSIPATION, TRANSMISSION AND RECEIVE PATHS ALL
ACTIVE ............................................................................................................................................................... 8
TABLE 5: AC ELECTRICAL CHARACTERISTICS ................................................................................................... 8
TABLE 6: DC ELECTRICAL CHARACTERISTICS .................................................................................................... 9
ABSOLUTE MAXIMUM RATINGS .......................................................................................................... 9
Figure 5. Receiver Maximum Jitter Tolerance, Test Conditions: Test Pattern 215-1, (-6dB) Cable Loss ..
10
Figure 6. Receiver Jitter Transfer Function (Jitter Attenuator Disabled), Test Conditions: Test Pattern
215-1, Input Jitter 0.5UIp-p ............................................................................................................................ 11
Figure 7. Receiver Jitter Transfer Function (Jitter Attenuator enabled) Test Conditions: Test Pattern 2151, Input Jitter 75% of Maximum Jitter Tolerance ........................................................................................ 11
SYSTEM DESCRIPTION .................................................................................................. 12
1.0 THE Receive Section ........................................................................................................................ 12
1.1 JITTER ATTENUATOR .................................................................................................................................. 12
1.2 THE TRANSMIT SECTION ............................................................................................................................ 12
Figure 8. Illustration on how the XRT82D20 Samples the data on the TPOS and TNEG input pins .... 12
1.3 THE PULSE SHAPING CIRCUIT ........................................................................................................................... 12
Figure 9. Illustration of the ITU-T G.703 Pulse Template for E1 Application .......................................... 13
1.4 INTERFACING THE TRANSMIT SECTION OF THE XRT82D20 TO THE LINE ............................................................. 14
Figure 10. Illustration of how to interface the XRT82D20 to the Line for 75 Ω Applications and 3.3V operation only .................................................................................................................................................... 14
Figure 11. Illustration of how to interface the XRT82D20 to the Line for 120 Ω Applications and 3.3V operation only .................................................................................................................................................... 15
1.5 INTERFACING THE RECEIVE SECTION TO THE LINE ............................................................................................. 15
Figure 12. Recommended Schematic for Transformer-Coupling the XRT82D20 to the Line for 75 Ω Applications and 5 V operation only ................................................................................................................ 16
Figure 13. Recommended Schematic for Transformer-Coupling the XRT82D20 to the Line for 120 Ω Applications and 5 V operation only ................................................................................................................ 17
1.6 CAPACITIVELY-COUPLING THE RECEIVE SECTION(S) OF THE XRT82D20 TO THE LINE ......................................... 18
Figure 14. Capacitively-coupling the Receive Section for 75 Ω Application and 3.3V supply .............
Figure 15. Capacitively-coupling the Receive Section for 120 Ω Application and 3.3V supply ...........
Figure 16. Capacitively-coupling the Receive Section for 75 Ω Application and 5V supply ................
Figure 17. Capacitively-coupling the Receive Section for 120 Ω Application and 5V supply ..............
2.0 Diagnostic Features .........................................................................................................................
18
19
20
21
22
2.1 THE LOCAL LOOP-BACK MODE ......................................................................................................................... 22
Figure 18. Illustration of the Analog Local Loop-Back within the XRT82D20 ........................................ 22
2.2 THE REMOTE LOOP BACK MODE ....................................................................................................................... 23
Figure 19. Illustration of the Remote Loop-Back path, within the XRT82D20 ........................................ 23
I
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
PACKAGE OUTLINE DRAWING ...................................................................................... 24
REVISION HISTORY ..................................................................................................................................... 25
II
XRT82D20
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
REV. 1.0.7
PIN DESCRIPTIONS
PIN #
SYMBOL
TYPE
DESCRIPTION
1
RLOS
O
Receiver Loss of Signal: This pin toggles Low to indicate the loss of
signal at the receive inputs.
2
ClkLOS
O
Receiver Loss of Clock: With MuteRx=1, this pin will toggle low to indicate a loss of clock has occurred when the receive signal is lost
(RLOS=0). When RLOS=0, no transitions occur on RClk, RPOS/RData
and RNEG outputs.
3
TNEG/CODE
I
Transmitter Negative Data Input/Coding Select: With Jitter Attenuator
enabled (pin 18=1), input activity on this pin determines whether the
device is configured to operate in single-rail or dual-rail mode. With n-rail
transmit data applied to this pin, the device is automatically configured to
operate in dual-rail mode for both transmit input and receive output.
If this pin is tied high for more than 16 clock cycles, the device is configured to operate in single-rail mode with HDB3 encoding and decoding
functions enabled.
If this pin is tied low for more than 16 clock cycles, the device is configured to operate in single-rail mode with AMI encoding and decoding
functions enabled. (internal pull-down).
4
RNEG/LCV
O
Receive Negative Data/Line Code Violation Output:
If the device is configured in Dual-rail mode with n-rail data applied to pin
3, then the receive negative data will be output through this pin.
If the device is configured in Single-rail mode and operate with HDB3
coding enabled, HDB3 code violation will be detected and cause this pin
to go high.
If the device is configured in Single-rail mode and with AMI coding
selected, every bipolar violation will be reported at this pin.
5
RClk
O
Receive Clock:
Output receive clock signal to the terminal equipment.
6
RPOS/RData
O
Receive Positive/ Data Output:
In Dual-rail mode, this signal is the p-rail receive output data. In Singlerail mode, this signal is the receive output data.
7
TClk
I
Transmitter Clock Input:
Input clock signal (2.048 MHz ± 50ppm)
8
TPOS/TData
I
Transmit Positive / Data Input:
In Dual-rail mode, this signal is the p-rail transmit input data. In Single-rail
mode, this signal is the transmit input data.
9
LLoop
I
Local Loop back enable (active low):
Tie this pin low to enable analog Local Loop-back.In local loop-back
mode, transmit output data is looped back to the input of the
receiver.Input signal at RTIP and RRing are ignored. Local Loop-back
has priority over Remote and Digital Loop-back mode. See Section 2.2
for more details. (internal pull-down).
10
RLoop
I
Remote Loop Back Enable (active low):
Connect this pin to ground to enable Remote Loop-back. In Remote
Loop-back mode, transmit data at TPOS/TData and TNEG are ignored.
See Section 2.2 for more details. (internal pull-down).
11
DLoop
I
Digital Loop Back enable (active low):
Connect this pin to ground to enable Digital Local Loop-back.In Digital
loop-back mode, transmit input data after the encoder is looped back to
the jitter attenuator (if selected) and to the receive decoder. Input data at
RTIP and RRing are ignored in this mode. (internal pull-up). In this
mode, the XRT82D20 can operate only as a jitter attenuator.
3
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
PIN #
SYMBOL
TYPE
12
ATM
I
Alarm Test Mode (Active-Low):
Connect this pin to ground to force ClkLOS, RLOS = 0 and LCV = 1 for
testing without affecting data transmission. (internal pull-up)
13
RAOS
I
Receive All Ones:
With this pin tied to High, an all “1’s” signal is inserted to the receiver output at RPOS and RNEG/RData using MCLK as timing reference. This
control has priority over Digital Loop-back if both are enabled. (internal
pull-down).
14
TAOS
I
Transmit All Ones:
With this pin tied High, an AMI encoded all “1’s” signal is sent to the
transmit output using MCLK as timing reference. This control has priority
over Remote Loop-back if both are enabled. (internal pull-down).
15
MClk
I
Master Clock Input:
This signal is an independent 2.048 MHz clock with accuracy better than
+ 50 ppM and duty cycle within 40% to 60%. The function of MClk is to
provide timing source for the PLL clock recovery circuit, reference clock
to insert all “1’s” data in the transmit as well as receive paths. This signal
must be available for the device to operate.
16
JATx/Rx
(DR/SR)
I
Jitter Attenuator Path Select:
With the jitter attenuator enabled, (pin 18 =”1”), tie this pin “High” to
select the jitter attenuator in the transmit path and tie it “Low” to select in
the receive path. Data input/output format is then controlled automatically by the status of the TNEG input. If TNEG data is present the device
operates in Dual-rail data mode.
Dual-Rail/Single-Rail Select:
With the jitter attenuator disabled, (pin 18 =”0”), tie this pin “High” to
select Dual-Rail data format and tie it “Low” to select Single-Rail data format. (internal pull-down)
17
DIGI
I
Digital Interface:
With this pin tied Low, input data at TPOS/TData and TNEG/CODE is
active-high and will be sampled by TClk on the falling edge, while activehigh RPOS/RData and RNEG output data are updated on the falling
edge of RClk. See Figure 3 and 4 for details.
With his pin tied high and in Dual-rail mode, transmit input accepts
active-low TPOS/TData and TNEG/CODE data and will be sampled by
TClk on the falling edge, while RPOS/RData and RNEG/LCV are activelow, data is updated on the rising edge of RClk. (internal pull-down).
18
JAEN
I
Jitter Attenuator Enable (active high):
Connect this pin high to enable the jitter attenuation function. Jitter Attenuator Path select is determined by the pin 16 setting. (internal pull-down)
19
TGND
-
Transmitter Supply Ground
20
TRing
O
Transmitter Ring Output:
Negative bipolar data output to the line.
21
TVDD
-
Transmit Positive Supply:
5.0 V + 5% or 3.3 V + 5%
22
TTIP
O
Transmitter TIP Output:
Positive bipolar data output to the line.
23
TxLEV
I
Transmit Level:
Tie this pin high for 120 Ω twisted pair cable operation and tie it low for 75
Ω coaxial cable operation (internal pull-down). This pin is only active for
5.0V operation.
DESCRIPTION
4
XRT82D20
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
REV. 1.0.7
PIN #
SYMBOL
TYPE
DESCRIPTION
24
AVDD
-
Analog Positive Supply
5.0 V + 5% or 3.3 V+ 5%
25
AGND
-
Analog Supply Ground
26
MuteRx
I
Mute Receive Output:
With this pin tied high, a loss of receive input signal (RLOS=0) will cause
ClkLOS to go low and generate the following.
Dual-rail mode operation:
With DIGI = 0, RClk = 1, RPOS and RNEG/RData = 0
fWith DIGI = 1, RClk =0, RPOS and RNEG/RData = 1
Single-rail mode:
RClk = 1 and RData=0
(internal pull-down)
27
RRing
I
Receive Bipolar Negative Input:
Bipolar line signal input to the receiver.
28
RTIP
I
Receiver Bipolar Positive Input:
Bipolar line signal input to the receiver.
FIGURE 3. INTERFACE TIMING DIAGRAM IN BOTH SINGLE-RAIL AND DUAL-RAIL MODE, WITH DIGI (PIN 17) = “0”
TClk
tr
tf
TClk
TPOS/TData
or
TNEG/CODE
Active High
tTSU
tTHO
tr
tRCD
tf
RClk
tRSU
RPOS/RData
or
RNEG/LCV
Active High
tRHO
5
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
FIGURE 4. INTERFACE TIMING DIAGRAM IN DUAL-RAIL MODE ONLY, WITH DIGI (PIN 17) = “1”
TClk
tr
tf
TClk
TPOS/TData
Active Low
t TSU
t THO
t RCD
tr
tf
RClk
t RSU
RPOS/RData
Active Low
t RHO
6
XRT82D20
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
REV. 1.0.7
ELECTRICAL CHARACTERISTICS
TABLE 1: RECEIVER CHARACTERISTICS
TA = 25°C, VDD = 3.3V± 5% or 5V± 5% Unless otherwise specified
MIN.
PARAMETER
TYP.
Receiver Sensitivity
0.7
Interference Margin with -6db Cable Loss
-18
-14
Input Impedance measured between RTIP or RRing to ground
MAX
UNIT
4.2
Vp
-
dB
0.9
2.0
-
kΩ
Recovered Clock Jitter Transfer Corner Frequency
Peaking Amplitude
-
18
0.1
36
0.5
kHz
dB
Jitter Attenuator Corner Frequency (-3dB curve)
-
20
40
Hz
12
18
14
25
35
25
-
dB
dB
dB
Return Loss
51kHz-102kHz
102kHz-2048kHz
2048kHz-3072kHz
TABLE 2: TRANSMITTER CHARACTERISTICS
TA = 25°C, VDD = 3.3V± 5% or 5V± 5% Unless otherwise specified
PARAMETER
MIN.
TYP.
MAX
UNIT
AMI Output Pulse Amplitude
75 Ω Application
120 Ω Application
2.14
2.70
2.37
3.00
2.60
3.30
V
V
Output Pulse Width
224
244
264
ns
Output Pulse Amplitude Ratio
0.9
1.0
1.1
Jitter Added by the Transmitter Output
-
0.025
0.050
UIpp
Output Return Loss:
51kHz -102kHz
102kHz-2048kHz
2048kHz-3072kHz
-
20
25
20
-
dB
dB
dB
TABLE 3: 3.3V POWER CONSUMPTION INCLUDING LINE POWER DISSIPATION, TRANSMISSION AND RECEIVE PATHS
ALL ACTIVE
TA = -40° to 85°C, VDD = 3.3V± 5% Unless otherwise specified
SYMBOL
PARAMETER
MIN.
TYP.
MAX
UNIT
PC
Power Consumption
-
100
140
mW
75Ω load, operating at 50% Mark Density
PC
Power Consumption
-
92
130
mW
120Ω load, operating at 50% Mark Density
PC
Power Consumption
-
150
190
mW
75Ω load, operating at 100% Mark Density
PC
Power Consumption
-
125
160
mW
120Ω load, operating at 100% Mark Density
7
CONDITIONS
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
TABLE 4: 5V POWER CONSUMPTION INCLUDING LINE POWER DISSIPATION, TRANSMISSION AND RECEIVE PATHS ALL
ACTIVE
(TA = -40° to 85°C, VDD = 5V ± 5% Unless otherwise specified)
SYMBOL
PARAMETER
MIN.
TYP.
MAX
UNIT
PC
Power Consumption
-
160
210
mW
75Ω load, operating at 50% Mark Density
PC
Power Consumption
-
145
195
mW
120Ω load, operating at 50% Mark Density
PC
Power Consumption
-
200
260
mW
75Ω load, operating at 100% Mark Density
PC
Power Consumption
-
180
240
mW
120Ω load, operating at 100% Mark Density
CONDITIONS
TABLE 5: AC ELECTRICAL CHARACTERISTICS
TA = -40 to +85 °C, VDD = 3.3V± 5% or 5V ± 5% Unless otherwise specified
PARAMETER
SYMBOL
MIN.
TYP
MAX
Clock Frequency
MClk
-50 ppm
2.048
+50ppm
Clock Duty Cycle
MClk
40
50
60
%
Clock Period
TClk
-
244
-
ns
TClk Duty Cycle
UNITS
MHz
TCDU
30
50
70
%
Transmit Data Setup Time
tTSU
40
-
-
ns
Transmit Data Hold Time
tTHO
40
-
-
ns
TClk Rise Time (10% /90%)
tr
-
-
40
ns
TClk Fall Time (90% / 10%)
tf
-
-
40
ns
RCDU
45
50
55
%
Receive Data Setup Time
tRSU
150
244
-
ns
Receive Data Hold Time
tRHO
150
244
-
ns
RClk to Data Delay
tRCD
-
-
40
ns
RClk Rise Time (10%/90%)
tr
-
-
40
ns
RClk Fall Time (90%/10%)
tf
-
-
40
ns
RClk Duty Cycle
8
XRT82D20
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
REV. 1.0.7
TABLE 6: DC ELECTRICAL CHARACTERISTICS
Ta = 25°C, Vdd=3.3V ± 5% or 5V ± 5% unless otherwise specified
PARAMETER
SYMBOL
MIN
TYP
MAX
Input High Voltage
VIH
2.0
3.3 or 5.0
5.5
V
Input Low Voltage
VIL
0.5
0
0.8
V
Output High Voltage @IOH=5mA (See Note)
VDD=3.3V
VDD=5.0v
VOH
2.4
2.4
Output Low Voltage @ IOL=5mA (See Note)
VDD=3.3V
VDD=5.0v
VOL
0
0
Input Leakage Current (except input pins with pull-up
resistors)
IL
-
0
10
uA
Input Capacitance
CI
-
5
20
pF
Output Load Capacitance
CO
-
-
20
pF
-
V
VDD
VDD
-
V
0.4
0.4
NOTE: All Digital output pins except pin 1 and pin 2, which
typically source 20µA at VOH and sink -4mA at VOL
ABSOLUTE MAXIMUM RATINGS
Storage Temperature
-65 to 150°C
Operating Temperature
-40 to 85°C
Supply Voltage
-0.5V to +5.5V
9
UNIT
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XRT82D20
SINGLE CHANNEL E1 LINE INTERFACE UNIT
REV. 1.0.7
FIGURE 5. RECEIVER MAXIMUM JITTER TOLERANCE, TEST CONDITIONS: TEST PATTERN 215-1, (-6dB) CABLE LOSS
3
10
JAT D isabled
2
10
Input Jitter (UIp−p)
JAT E nab led
1
10
IT U -T G .823 M ask
0
10
−1
10
0
10
1
10
2
3
10
10
(Freq.(MHz))
10
4
10
5
10
XRT82D20
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SINGLE CHANNEL E1 LINE INTERFACE UNIT
REV. 1.0.7
FIGURE 6. RECEIVER JITTER TRANSFER FUNCTION (JITTER ATTENUATOR DISABLED), TEST CONDITIONS: TEST PAT15
TERN 2 -1, INPUT JITTER 0.5UIP-P
2
G .735-G 739 S pecification
0
−2
−4
20log(Jout/Jin) (dB)
T 82D 20 P erform ance
−6
−8
−10
−12
−14
2
3
10
4
10
5
10
10
(Freq.(MHz))
FIGURE 7. RECEIVER JITTER TRANSFER FUNCTION (JITTER ATTENUATOR ENABLED) TEST CONDITIONS: TEST PATTERN 215-1, INPUT JITTER 75% OF MAXIMUM JITTER TOLERANCE
10
ITU .G .736 M ask
0
Jitter Attenuation (dB)
−10
−20
−30
T 82D 20 P erform ance
−40
−50
−60
0
10
1
10
2
3
10
10
(Freq.(MHz))
11
4
10
5
10
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SINGLE CHANNEL LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
SYSTEM DESCRIPTION
coming line signal) to the Receive Terminal Equipment via the RPOS and RNEG output pins.
If the Receive Section of the XRT82D20 has received
a Positive-Polarity pulse, via the RTIP and
RRing input pins, then the Receive Output Interface
will output a pulse at the RPOS output pin.
Similarly, if the Receive Section of the XRT82D20 has
received a Negative-Polarity pulse, via the RTIP and
RRing input pins, then the Receive Output Interface
will output a pulse at the RNEG output pin.
The XRT82D20 is a single channel E1 transceiver
that provides an electrical interface for 2.048Mbps applications. XRT82D20 includes a receive circuit that
converts an ITU-T G.703 compliant bipolar signal into
a TTL compatible logic levels. The receiver also includes an LOS (Loss of Signal) detection circuit.
Similarly, in the Transmit Direction, the Transmitter
converts TTL compatible logic levels into a G.703
compatible bipolar signal.
The XRT82D20 consists of both a Receive Section,
Jitter Attenuator and Transmit Section; each of these
sections will be discussed below.
1.1 JITTER ATTENUATOR
To reduce frequency jitter in the transmit clock or receive clock, a crystal-less jitter attenuator is provided.
The jitter attenuator can be selected either in the
transmit or receive path or it can be disabled.
1.0 THE RECEIVE SECTION
At the receiver input, cable attenuated AMI signal can
be coupled to the receiver using a capacitor or transformer. The receive data first goes through the peak
detector and data slicer for accurate data recovery.The digital representation of the AMI signals go to
the clock recovery circuit for timing recovery and subsequently to the decoder (if selected) for HDB3 decoding before being output to the RPOS/RData and
RNEG/LCV pins. The digital data output can be in
NRZ or RZ format depending the mode of operation
selected and with the option to be in dual-rail or single
rail mode. Clock timing recovery of the line interface
is accomplished by means of a digital PLL scheme
which has high input jitter tolerance.
1.2 THE TRANSMIT SECTION
In general, the purpose of the Transmit Section (within the XRT82D20) is to accept TTL/CMOS level digital
data (from the Terminal Equipment), and to encode it
into a format such that it can:
1. Be efficiently transmitted over coaxial- or twisted
pair cable at the E1 data rate; and
2. Be reliably received by the Remote Terminal
Equipment at the other end of the E1 data link.
3. Comply with the ITU-T G.703 pulse template
requirements, for E1 applications
A 2.048 MHz clock is applied to the TClk input pin
and NRZ data at the TPOS and TNEG input pins.
The Transmit Input Interface circuit will sample the
data, at the TPOS and TNEG input pins, upon the falling edge of TClk, as illustrated in Figure 8 below.
The purpose of the Receive Output Interface block is
to interface directly with the Receiving Terminal
Equipment. The Receive Output Interface block outputs the data (which has been recovered from the in-
FIGURE 8. ILLUSTRATION ON HOW THE XRT82D20 SAMPLES THE DATA ON THE TPOS AND TNEG INPUT PINS
tSU
tHO
TPOS
TNEG
TClk
In general, if the XRT82D20 samples a “1” on the
TPOS input pin, then the Transmit Section will ultimately generate a positive polarity pulse via the TTIP
and TRing output pins (across a 1:2 transformer).
Conversely, if the XRT82D20 samples a “1” on the
TNEG input pin, then the Transmit Section of the de-
vice will ultimately generate a negative polarity pulse
via the TTIP and TRing output pins (across a 1:2
transformer).
1.3 THE PULSE SHAPING CIRCUIT
The purpose of the Transmit Pulse Shaping circuit is
to generate Transmit Output pulses that comply with
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SINGLE CHANNEL LINE INTERFACE UNIT
REV. 1.0.7
Transmit Input Interface block, and will generate a
pulse that complies with the pulse template, presented in Figure 9 (when measured on the secondary
side of the Transmit Output Transformer).
the ITU-T G.703 Pulse Template Requirements for E1
Applications.
An illustration of the ITU-T G.703 Pulse Template Requirements is presented below in Figure 9.
With input signal as described above, the XRT82D20
will take each mark (which is provided to it via the
FIGURE 9. ILLUSTRATION OF THE ITU-T G.703 PULSE TEMPLATE FOR E1 APPLICATION
194 ns
(244 – 50)
20%
V = 100%
10%
10%
20%
269 ns
(244 + 25)
Nominal pulse
50%
10%
20%
0%
10%
10%
219 ns
(244 – 25)
10%
244 ns
488 ns
(244 + 244)
Note – V corresponds to the nominal peak value.
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SINGLE CHANNEL LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
In both applications (e.g., 75Ω or 120Ω, the user is advised to interface the Transmitter to the Line, in the
manner as depicted in Figure 10 and Figure 11, respectively.
1.4 INTERFACING THE TRANSMIT SECTION OF THE
XRT82D20 TO THE LINE
ITU-T G.703 specifies that the E1 line signal can be
transmitted over coaxial cable and terminated with
75Ω or transmitted over twisted-pair and terminated
with 120Ω.
FIGURE 10. ILLUSTRATION OF HOW TO INTERFACE THE XRT82D20 TO THE LINE FOR 75 Ω APPLICATIONS AND 3.3V
OPERATION ONLY
75 Ω Coax
RPOS/RData
1:2
RTIP
RNEG/LCV
270 Ω
75 Ω
Signal
Source
RClk
Rxx Input
270 Ω
TVDD
+3.3 V
AVDD
RRING
10µF
75 Ω Coax
TxLEV
2:1
TTIP
9.1 Ω
TGND
AGND
R Load
75 Ω
Tx Output
TNEG/CODE
9.1 Ω
TPOS/TData
TRING
TClk
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SINGLE CHANNEL LINE INTERFACE UNIT
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FIGURE 11. ILLUSTRATION OF HOW TO INTERFACE THE XRT82D20 TO THE LINE FOR 120 Ω APPLICATIONS AND
3.3V OPERATION ONLY
120 Ω Twisted Pair
RPOS/RData
1:2
RTIP
RNEG/LCV
866 Ω
120 Ω
Signal
Source
RClk
Rx Input
866 Ω
TVDD
+3.3 V
AVDD
RRING
120 Ω Twisted Pair
10 µF
0.1 µF
TxLEV
2:1
TTIP
9.1 Ω
TGND
AGND
R Load
120 Ω
Tx Output
TNEG/CODE
9.1 Ω
TPOS/TData
TRING
TClk
NOTES:
1. Figure 10 and Figure 11indicate that for 3.3 V operation, both 75 Ω and 120 Ω applications, the user
should connect a 9.1Ω resistor in series between
the TTIP/TRing outputs and the transformer.
2. Figure 10 and Figure 11indicate that the user
should use a 2 : 1 STEP-UP Transformer.
1.5 INTERFACING THE RECEIVE SECTION TO THE LINE
The design of the XRT82D20 permits the user to
transformer-couple the Receive Section to the line.
As mentioned earlier, the specifications for E1 require
75Ω termination loads, when transmitting over coaxial
cable, and 120Ω loads, when transmitting over twisted-pair. Figure 12 and Figure 13 present the various
methods that the user can employ to interface the Receiver of the XRT82D20 to the line.
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SINGLE CHANNEL LINE INTERFACE UNIT
XRT82D20
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FIGURE 12. RECOMMENDED SCHEMATIC FOR TRANSFORMER-COUPLING THE XRT82D20 TO THE LINE FOR 75 Ω
APPLICATIONS AND 5 V OPERATION ONLY
75 Ω Coax
RPOS/RData
1:2
RTIP
RNEG/LCV
270 Ω
75 Ω
Signal
Source
RClk
Rx Input
270 Ω
TVDD
+5 V
AVDD
RRING
10 µF
75 Ω Coax
TxLEV
1.36 : 1
TTIP
15.4 Ω
R Load
75 Ω
TGND
AGND
Tx Output
TNEG/CODE
15.4 Ω
TPOS/TData
TRING
TClk
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SINGLE CHANNEL LINE INTERFACE UNIT
REV. 1.0.7
FIGURE 13. RECOMMENDED SCHEMATIC FOR TRANSFORMER-COUPLING THE XRT82D20 TO THE LINE FOR 120 Ω
APPLICATIONS AND 5 V OPERATION ONLY
120 Ω Twisted Pair
RPOS/RData
1:2
RTIP
RNEG/LCV
866 Ω
120 Ω
Signal
Source
RClk
Rx Input
866 Ω
TVDD
+5 V
AVDD
RRING
10 µF
120 Ω Twisted Pair
TxLEV
1.36 : 1
TTIP
26.1 Ω
TGND
AGND
R Load
120 Ω
Tx Output
TNEG/CODE
26.1 Ω
TPOS/TData
TRING
TClk
NOTE: Figure 12 and Figure 13indicate that the user should
use a 1.36 :1 STEP-UP transformer, when interfacing the
receiver to the line.
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SINGLE CHANNEL LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
1.6 CAPACITIVELY-COUPLING THE RECEIVE SECTION(S) OF THE XRT82D20 TO THE LINE
Capacitive coupling provides a lower cost interface to
the line. It must be noted that the line isolation is limited to the breakdown voltage of the capactior versus
the typical transformer isolation of 1,500 to 3,000
volts. With a capacitor there is also no DC isolation to
ground as there is with with a transformer.
Applications that are not sensitive to these issues can
benefit from the lower cost approach of using capacitor coupling on the receive input.
See Figure 14, Figure 15, Figure 16 and Figure 17 for
the recommended schematics for capacitively coupling the receiver to the line.
FIGURE 14. CAPACITIVELY-COUPLING THE RECEIVE SECTION FOR 75 Ω APPLICATION AND 3.3V SUPPLY
75 Ω Coax
RPOS/RData
RTIP
RNEG/LCV
37.4 Ω
75 Ω
Signal
Source
0.1 µF
RClk
Rx Input
37.4 Ω
TVDD
0.1 µF
+3.3 V
AVDD
RRING
10µF
75 Ω Coax
TxLEV
2:1
TTIP
9.1 Ω
TGND
AGND
Tx Output
R Load
75 Ω
TNEG/CODE
9.1 Ω
TPOS/TData
TRING
TClk
NOTE: Resistive divider attenuates the input signal by onehalf for both 75 Ω and 120 Ω applications.
18
0.1µF
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SINGLE CHANNEL LINE INTERFACE UNIT
REV. 1.0.7
FIGURE 15. CAPACITIVELY-COUPLING THE RECEIVE SECTION FOR 120 Ω APPLICATION AND 3.3V SUPPLY
120 Ω Twisted Pair
RPOS/RData
RTIP
RNEG/LCV
30.1 Ω
120 Ω
Signal
Source
0.1 µF
Rx Input
60.4 Ω
30.1 Ω
RClk
TVDD
0.1 µF
+3.3 V
AVDD
RRING
10 µF
120 Ω Twisted Pair
TxLEV
2:1
TTIP
9.1 Ω
TGND
AGND
Tx Output
R Load
120 Ω
TNEG/CODE
9.1 Ω
TPOS/TData
TRING
TClk
NOTE: Resistive divider attenuates the input signal by onehalf for both 75 Ω and 120 Ω applications.
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SINGLE CHANNEL LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
FIGURE 16. CAPACITIVELY-COUPLING THE RECEIVE SECTION FOR 75 Ω APPLICATION AND 5V SUPPLY
75 Ω Coax
RPOS/RData
RTIP
RNEG/LCV
0.1 µF
75 Ω
Signal
Source
RClk
Rx Input
37.4 Ω
TVDD
0.1 µF
+5 V
AVDD
RRING
10 µF
75 Ω Coax
TxLEV
1.36:1
TTIP
15.4 Ω
TGND
AGND
Tx Output
R Load
75 Ω
TNEG/CODE
15.4 Ω
TPOS/TData
TRING
TClk
NOTE: Resistive divider attenuates the input signal by onehalf for both 75 Ω and 120 Ω applications.
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SINGLE CHANNEL LINE INTERFACE UNIT
REV. 1.0.7
FIGURE 17. CAPACITIVELY-COUPLING THE RECEIVE SECTION FOR 120 Ω APPLICATION AND 5V SUPPLY
120 Ω Twisted Pair
RPOS/RData
RTIP
RNEG/LCV
30.1 Ω
120 Ω
Signal
Source
0.1 µF
60.4 Ω
30.1 Ω
RClk
Rx Input
TVDD
0.1 µF
+5 V
AVDD
RRING
10 µF
120 Ω Twisted Pair
TxLEV
1.36:1
TTIP
26.1 Ω
TGND
AGND
Tx Output
R Load
120 Ω
TNEG/CODE
26.1 Ω
TPOS/TData
TRING
TClk
NOTE: Resistive divider attenuates the input signal by onehalf for both 75 Ω and 120 Ω applications.
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SINGLE CHANNEL LINE INTERFACE UNIT
XRT82D20
REV. 1.0.7
2.0 DIAGNOSTIC FEATURES
In order to support diagnostic operations, the
XRT82D20 supports the following loop-back modes:
• Local Loopback
Shaping circuit. Finally, this data will be output to the
line via the TTIP and TRing output pins. Additionally,
this data (which is being output via the TTIP and
TRing output pins) will be looped back into the Receiver block. As a consequence, this data will also be
processed through the entire Receive Section of the
XRT82D20. After this post-loop-back data has been
processed through the Receive Section it will output,
to the Near-End Receiving Terminal Equipment via
the RPOS and RNEG output pins.
Figure 18, illustrates the path that the data takes
(within the XRT82D20), when the chip is configured
to operate in the Local Loop-Back Mode.
The user can configure the XRT82D20 to operate in
the Local Loop-Back Mode, by pulling the LLoop input
pin (pin 9) to GND.
• Remote Loopback
• Digital Loopback
Each of these loop-back modes will be discussed below.
2.1 THE LOCAL LOOP-BACK MODE
When the XRT82D20 is configured to operate in the
Local Loop-Back Mode, the XRT82D20 will ignore
any signals that are input to the RTIP and RRing input
pins. The Transmitting Terminal Equipment will transmit data into the XRT82D20 via the TPOS, TNEG and
TClk input pins. This data will be processed through
the Transmit Terminal Input Interface and the Pulse
FIGURE 18. ILLUSTRATION OF THE ANALOG LOCAL LOOP-BACK WITHIN THE XRT82D20
TClk
TPOS
TNEG
TTIP
HDB3
Encoder
Tx Pulse
Shaper
MUX
Line
Driver
TRing
Jitter Attenuator
Local
Loopback
LOS
Detect
RClk
RPOS
RNEG
HDB3
Decoder
Data &
Timing
Recovery
MUX
Timing
Generator
22
Data
Slicer
RLOS
Peak
Detector
RTIP
RRing
MClk
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SINGLE CHANNEL LINE INTERFACE UNIT
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2.2 THE REMOTE LOOP BACK MODE
When the XRT82D20 is configured to operate in the
Remote Loop-Back Mode, the XRT82D20 will ignore
any signals that are input to the TPOS and TNEG input pins. The XRT82D20 will receive the incoming
line signals, via the RTIP and RRing input pins. This
data will be processed through the entire Receive
Section (within the XRT82D20) and will output to the
Receive Terminal Equipment via the RPOS and
RNEG output pins. Additionally, this data will also be
internally looped back to the Transmit Input Interface
block within the Transmit Section. At this point, this
data will be routed through the remainder of the
Transmit Section of the XRT82D20 and will be transmitted out onto the line via the TTIP and TRing output
pins.
Figure 19, illustrates the path that the data takes
(within the XRT82D20) when the chip is configured to
operate in the Remote Loop-Back Mode.
FIGURE 19. ILLUSTRATION OF THE REMOTE LOOP-BACK PATH, WITHIN THE XRT82D20
TClk
TPOS
TNEG
TTIP
HDB3
Encoder
Tx Pulse
Shaper
MUX
Line
Driver
TRing
Jitter Attenuator
Remote
Loopback
RClk
RPOS
RNEG
HDB3
Decoder
LOS
Detect
Data &
Timing
Recovery
MUX
Timing
Generator
NOTE: During Remote Loop-Back operation, any data
which is input via the RTIP and RRING input pins, will also
Data
Slicer
RLOS
Peak
Detector
RTIP
RRing
MClk
be output to the Terminal Equipment, via the RPOS and
RNEG output pins.
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XRT82D20
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PACKAGE OUTLINE DRAWING
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XRT82D20
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SINGLE CHANNEL LINE INTERFACE UNIT
REV. 1.0.7
REVISION HISTORY
Rev. 1.0.6 corrections to figures, remove values from pull-up/down resistors, correct formating of ±.
Rev. 1.0.7 Minor edits of figures and text. Added 4 new figures 14, 15, 16 and 17, showing capacitive coupling of the receiver to the line.
NOTICE
EXAR Corporation reserves the right to make changes to the products contained in this publication in order
to improve design, performance or reliability. EXAR Corporation assumes no responsibility for the use of
any circuits described herein, conveys no license under any patent or other right, and makes no representation that the circuits are free of patent infringement. Charts and schedules contained here in are only for
illustration purposes and may vary depending upon a user’s specific application. While the information in
this publication has been carefully checked; no responsibility, however, is assumed for inaccuracies.
EXAR Corporation does not recommend the use of any of its products in life support applications where
the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless EXAR Corporation receives, in writing, assurances to its satisfaction that: (a) the risk of injury
or damage has been minimized; (b) the user assumes all such risks; (c) potential liability of EXAR Corporation is adequately protected under the circumstances.
Copyright 2001 EXAR Corporation
Datasheet April 2001
Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited.
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