XRT83SL28
xr
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
APRIL 2005
REV. 1.0.0
GENERAL DESCRIPTION
The XRT83SL28 is a fully integrated 8-channel E1
short-haul LIU which optimizes system cost and
performance by offering key design features. The
XRT83SL28 operates from a single 3.3V power
supply. The LIU features are programmed through a
standard serial microprocessor interface or hardware
control. EXAR’s LIU has patented high impedance
circuits that allow the transmitter outputs and receiver
inputs to be high impedance when experiencing a
power failure or when the LIU is powered off. Key
design features within the LIU optimize 1:1 or 1+1
redundancy and non-intrusive monitoring applications
to ensure reliability without using relays.
Additional features include TAOS for transmit and
receive, RLOS, LCV, AIS, DMO, and diagnostic
loopback modes.
APPLICATIONS
•
•
•
•
•
•
•
•
ISDN Primary Rate Interface
CSU/DSU E1 Interface
E1 LAN/WAN Routers
Public Switching Systems and PBX Interfaces
E1 Multiplexer and Channel Banks
Integrated Multi-Service Access Platforms (IMAPs)
Integrated Access Devices (IADs)
Inverse Multiplexing for ATM (IMA) Wireless Base
Stations
FIGURE 1. HOST MODE BLOCK DIAGRAM OF THE XRT83SL28
1 of 8 Channels
Driver
Monitor
TCLK
TPOS
TNEG
HDB3
Encoder
Timing
Control
Remote
Loopback
RCLK
RPOS
RNEG/LCV
Jitter
Attenuator
(Rx or Tx)
HDB3
Decoder
TTIP
Line
Driver
TRING
Analog
Loopback
Digital
Loopback
Clock & Data
Recovery
RLOS
Peak
Detector
& Slicer
Rx
Equalizer
RTIP
RRING
AIS & LOS
Detector
Test
Clock Distribution
Reset
HW/Host
SDI
SDO
CS
SCLK
INT
Serial Microprocessor
Interface
TxOE
MCLK
ICT
Tx Pulse
Shaper
DMO
Exar Corporation 48720 Kato Road, Fremont CA, 94538 • (510) 668-7000 • FAX (510) 668-7017 • www.exar.com
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
FIGURE 2. HARDWARE MODE BLOCK DIAGRAM OF THE XRT83SL28
1 of 8 Channels
Driver
Monitor
TCLK
TPOS
TNEG/CODE
HDB3
Encoder
Remote
Loopback
RCLK
RPOS
RNEG/LCV
Timing
Control
Jitter
Attenuator
(Rx or Tx)
HDB3
Decoder
TTIP
Line
Driver
TRING
Analog
Loopback
Digital
Loopback
Clock & Data
Recovery
RLOS
Peak
Detector
& Slicer
Rx
Equalizer
RTIP
RRING
AIS & LOS
Detector
Test
Clock Distribution
MCLK
Reset
HW/Host
LBM[1:0]
JASEL[1:0]
FIFOS
CHLB[3:0]
Hardware Configuration
SR/DR
TERSEL[1:0]
TCLKinv
RCLKinv
ICT
Tx Pulse
Shaper
DMO
2
TxOE
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REV. 1.0.0
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
FEATURES
• Fully integrated 8-Channel short haul transceivers for E1 (2.048MHz) applications.
• Internal Impedance matching on both receive and transmit for 75Ω (E1) or 120Ω (E1) applications.
• Tri-State on a per channel basis for the transmit selection.
• On-Chip transmit short-circuit protection and limiting protects line drivers from damage on a per channel
basis.
• Independent Crystal-Less digital jitter attenuators (JA) with 32-Bit or 64-Bit FIFO for the receive or transmit
paths
• Driver failure monitor output (DMO) alerts of possible system or external component problems.
• Transmit outputs and receive inputs may be "High" impedance for protection or redundancy applications on a
per channel basis.
• Support for automatic protection switching.
• 1:1 and 1+1 protection without relays.
• RLOS/AIS according to ITU-T G.775 or ETSI-300-233.
• On-Chip HDB3 encoder/decoder for each channel.
• On-Chip digital clock recovery circuit for high input jitter tolerance.
• Line code error and bipolar violation detection.
• Transmit all ones (TAOS) for the Transmit and Receive Outputs.
• Supports local analog, remote, and digital loopback modes.
• Supports gapped clocks for mapper/multiplexer applications.
• Low Power dissipation
• Single 3.3V supply operation (3V to 5V I/O tolerant).
• 144-Pin TQFP package
• -40°C to +85°C Temperature Range
PRODUCT ORDERING INFORMATION
PRODUCT NUMBER
PACKAGE TYPE
OPERATING TEMPERATURE RANGE
XRT83SL28IV
144 Lead TQFP
-40°C to +85°C
3
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
DMO4
TCLKinv
RTIP4
RRING4
TGND4
TTIP4
TVDD4
TRING4
INT
TRING5
TVDD5
TTIP5
TGND5
RRING5
RTIP5
DVDDcore
SDI/CHLB0
SDO/CHLB1
SCLK/CHLB2
CS/CHLB3
DGNDcore
RTIP6
RRING6
TGND6
TTIP6
TVDD6
TRING6
HW/Host
TRING7
TVDD7
TTIP7
TGND7
RRING7
RTIP7
RCLKinv
DMO7
FIGURE 3. PIN OUT OF THE XRT83SL28
XRT83SL28
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
26
27
28
29
30
31
32
33
34
35
36
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
DMO0
SR/DR
RTIP0
RRING0
TGND0
TTIP0
TVDD0
TRING0
TxOE
TRING1
TVDD1
TTIP1
TGND1
RRING1
RTIP1
AVDD
MCLK
AGND
FIFOS
JASEL1
JASEL0
RTIP2
RRING2
TGND2
TTIP2
TVDD2
TRING2
RESET
TRING3
TVDD3
TTIP3
TGND3
RRING3
RTIP3
ICT
DMO3
DMO5
TNEG4/CODE4
TPOS4/TDATA4
TCLK4
TNEG5/CODE5
TPOS5/TDATA5
TCLK5
RLOS5
RNEG5/LCV5
RPOS5/RDATA5
RCLK5
RLOS4
RNEG4/LCV4
RPOS4/RDATA4
RCLK4
TERSEL0
TERSEL1
RGND2
RVDD2
DGND2
DVDD2
RCLK0
RPOS0/RDATA0
RNEG0/LCV0
RLOS0
RCLK1
RPOS1/RDATA1
RNEG1/LCV1
RLOS1
TCLK1
TPOS1/TDATA1
TNEG1/CODE1
TCLK0
TPOS0/TDATA0
TNEG0/CODE0
DMO1
4
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
DMO6
TNEG7/CODE7
TPOS7/TDATA7
TCLK7
TNEG6/CODE6
TPOS6/TDATA6
TCLK6
RLOS6
RNEG6/LCV6
RPOS6/RDATA6
RCLK6
RLOS7
RNEG7/LCV7
RPOS7/RDATA7
RCLK7
LBM0
LBM1
RGND1
RVDD1
DGND1
DVDD1
RCLK3
RPOS3/RDATA3
RNEG3/LCV3
RLOS3
RCLK2
RPOS2/RDATA2
RNEG2/LCV2
RLOS2
TCLK2
TPOS2/TDATA2
TNEG2/CODE2
TCLK3
TPOS3/TDATA3
TNEG3/CODE3
DMO2
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REV. 1.0.0
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
TABLE OF CONTENTS
GENERAL DESCRIPTION................................................................................................. 1
APPLICATIONS........................................................................................................................................... 1
FIGURE 1. HOST MODE BLOCK DIAGRAM OF THE XRT83SL28 ......................................................................................................... 1
FIGURE 2. HARDWARE MODE BLOCK DIAGRAM OF THE XRT83SL28 ................................................................................................ 2
FEATURES ..................................................................................................................................................... 3
PRODUCT ORDERING INFORMATION.................................................................................................. 3
FIGURE 3. PIN OUT OF THE XRT83SL28 ......................................................................................................................................... 4
TABLE OF CONTENTS ............................................................................................................ I
PIN DESCRIPTIONS .......................................................................................................... 5
SERIAL MICROPROCESSOR INTERFACE ............................................................................................................ 5
RECEIVER SECTION ....................................................................................................................................... 6
TRANSMITTER SECTION.................................................................................................................................. 7
CONTROL FUNCTION ...................................................................................................................................... 8
POWER AND GROUND (HOST AND HARDWARE MODES).................................................................................... 9
HARDWARE MODE INTERFACE ....................................................................................................................... 10
1.0 RECEIVE PATH LINE INTERFACE .................................................................................................... 14
FIGURE 4. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE PATH LINE TERMINATION (RTIP/RRING)................................................. 14
1.1 INTERNAL TERMINATION ............................................................................................................................ 14
TABLE 1: SELECTING THE INTERNAL IMPEDANCE ............................................................................................................................. 14
FIGURE 5. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION .................................................................................... 14
1.2 PEAK DETECTOR/DATA SLICER ................................................................................................................. 15
1.3 CLOCK AND DATA RECOVERY ................................................................................................................... 15
FIGURE 6. RECEIVE DATA UPDATED ON THE RISING EDGE OF RCLK .............................................................................................. 15
FIGURE 7. RECEIVE DATA UPDATED ON THE FALLING EDGE OF RCLK ............................................................................................ 15
TABLE 2: TIMING SPECIFICATIONS FOR RCLK/RPOS/RNEG .......................................................................................................... 15
1.4 RECEIVE SENSITIVITY .................................................................................................................................. 16
FIGURE 8. TEST CONFIGURATION FOR MEASURING RECEIVE SENSITIVITY ........................................................................................ 16
1.5 GENERAL ALARM DETECTION AND INTERRUPT GENERATION ............................................................ 16
1.5.1 RLOS (RECEIVER LOSS OF SIGNAL)...................................................................................................................... 17
1.5.2 AIS (ALARM INDICATION SIGNAL) .......................................................................................................................... 17
1.5.3 LCV (LINE CODE VIOLATION DETECTION) ............................................................................................................ 17
1.6 RECEIVE JITTER ATTENUATOR .................................................................................................................. 17
1.7 HDB3 DECODER ............................................................................................................................................ 18
1.8 ARAOS (AUTOMATIC RECEIVE ALL ONES) ............................................................................................... 18
FIGURE 9. SIMPLIFIED BLOCK DIAGRAM OF THE ARAOS FUNCTION ................................................................................................ 18
1.9 RPOS/RNEG/RCLK ........................................................................................................................................ 18
FIGURE 10. SINGLE RAIL MODE WITH A FIXED REPEATING "0011" PATTERN ................................................................................... 18
FIGURE 11. DUAL RAIL MODE WITH A FIXED REPEATING "0011" PATTERN ...................................................................................... 19
2.0 TRANSMIT PATH LINE INTERFACE ................................................................................................. 20
FIGURE 12. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT PATH ................................................................................................... 20
2.1 TCLK/TPOS/TNEG DIGITAL INPUTS ............................................................................................................ 20
FIGURE 13. TRANSMIT DATA SAMPLED ON FALLING EDGE OF TCLK ............................................................................................... 20
FIGURE 14. TRANSMIT DATA SAMPLED ON RISING EDGE OF TCLK ................................................................................................. 20
TABLE 3: TIMING SPECIFICATIONS FOR TCLK/TPOS/TNEG ........................................................................................................... 21
2.2 HDB3 ENCODER ............................................................................................................................................ 21
TABLE 4: EXAMPLES OF HDB3 ENCODING ...................................................................................................................................... 21
2.3 TRANSMIT JITTER ATTENUATOR ............................................................................................................... 21
TABLE 5: MAXIMUM GAP WIDTH FOR MULTIPLEXER/MAPPER APPLICATIONS .................................................................................... 21
2.4 TAOS (TRANSMIT ALL ONES) ..................................................................................................................... 22
FIGURE 15. TAOS (TRANSMIT ALL ONES)ATAOS (AUTOMATIC TRANSMIT ALL ONES) .................................................................... 22
2.5 ATAOS (AUTOMATIC TRANSMIT ALL ONES) ............................................................................................ 22
FIGURE 16. SIMPLIFIED BLOCK DIAGRAM OF THE ATAOS FUNCTION............................................................................................... 22
2.6 TRANSMITTER POWER DOWN IN HARDWARE MODE ............................................................................. 22
2.7 DMO (DRIVER MONITOR OUTPUT) ............................................................................................................. 22
2.8 LINE TERMINATION (TTIP/TRING) ............................................................................................................... 23
FIGURE 17. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION ................................................................................... 23
3.0 E1 APPLICATIONS ............................................................................................................................. 24
3.1 LOOPBACK DIAGNOSTICS .......................................................................................................................... 24
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�XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
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REV. 1.0.0
3.1.1 LOCAL ANALOG LOOPBACK .................................................................................................................................. 24
FIGURE 18. SIMPLIFIED BLOCK DIAGRAM OF LOCAL ANALOG LOOPBACK ......................................................................................... 24
3.1.2 REMOTE LOOPBACK ................................................................................................................................................ 24
FIGURE 19. SIMPLIFIED BLOCK DIAGRAM OF REMOTE LOOPBACK .................................................................................................... 24
3.1.3 DIGITAL LOOPBACK ................................................................................................................................................. 25
FIGURE 20. SIMPLIFIED BLOCK DIAGRAM OF DIGITAL LOOPBACK ..................................................................................................... 25
3.2 LINE CARD REDUNDANCY ........................................................................................................................... 26
3.2.1 1:1 AND 1+1 REDUNDANCY WITHOUT RELAYS .................................................................................................... 26
3.2.2 TRANSMIT INTERFACE WITH 1:1 AND 1+1 REDUNDANCY .................................................................................. 26
FIGURE 21. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR 1:1 AND 1+1 REDUNDANCY ......................................... 26
3.2.3 RECEIVE INTERFACE WITH 1:1 AND 1+1 REDUNDANCY..................................................................................... 27
FIGURE 22. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR 1:1 AND 1+1 REDUNDANCY ........................................... 27
3.2.4 N+1 REDUNDANCY USING EXTERNAL RELAYS ................................................................................................... 27
3.2.5 TRANSMIT INTERFACE WITH N+1 REDUNDANCY ................................................................................................ 28
FIGURE 23. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR N+1 REDUNDANCY ...................................................... 28
3.2.6 RECEIVE INTERFACE WITH N+1 REDUNDANCY ................................................................................................... 29
FIGURE 24. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR N+1 REDUNDANCY ........................................................ 29
3.3 POWER FAILURE PROTECTION .................................................................................................................. 30
3.4 OVERVOLTAGE AND OVERCURRENT PROTECTION ............................................................................... 30
3.5 NON-INTRUSIVE MONITORING .................................................................................................................... 30
FIGURE 25. SIMPLIFIED BLOCK DIAGRAM OF A NON-INTRUSIVE MONITORING APPLICATION............................................................... 30
4.0 SERIAL MICROPROCESSOR INTERFACE BLOCK ..........................................................................31
FIGURE 26. SIMPLIFIED BLOCK DIAGRAM OF THE SERIAL MICROPROCESSOR INTERFACE ................................................................. 31
4.1 SERIAL TIMING INFORMATION .................................................................................................................... 31
FIGURE 27. TIMING DIAGRAM FOR THE SERIAL MICROPROCESSOR INTERFACE ................................................................................ 31
4.2 16-BIT SERIAL DATA INPUT DESCRIPTION ............................................................................................... 32
4.2.1
4.2.2
4.2.3
4.2.4
R/W (SCLK1)...............................................................................................................................................................
A[5:0] (SCLK2 - SCLK7).............................................................................................................................................
X (DUMMY BIT SCLK8) ..............................................................................................................................................
D[7:0] (SCLK9 - SCLK16)...........................................................................................................................................
32
32
32
32
4.3 8-BIT SERIAL DATA OUTPUT DESCRIPTION ............................................................................................. 32
TABLE 6: MICROPROCESSOR REGISTER DESCRIPTION .................................................................................................................... 33
TABLE 7: MICROPROCESSOR REGISTER 0X00H BIT DESCRIPTION ................................................................................................... 35
TABLE 8: MICROPROCESSOR REGISTER 0X01H BIT DESCRIPTION ................................................................................................... 36
TABLE 9: MICROPROCESSOR REGISTER 0X02H BIT DESCRIPTION ................................................................................................... 36
TABLE 10: MICROPROCESSOR REGISTER BIT DESCRIPTION ............................................................................................................ 36
TABLE 11: MICROPROCESSOR REGISTER BIT DESCRIPTION ............................................................................................................ 38
TABLE 12: MICROPROCESSOR REGISTER BIT DESCRIPTION ............................................................................................................ 38
TABLE 13: MICROPROCESSOR REGISTER BIT DESCRIPTION ............................................................................................................ 39
ELECTRICAL CHARACTERISTICS ................................................................................41
TABLE 14:
TABLE 15:
TABLE 16:
TABLE 17:
TABLE 18:
TABLE 19:
ABSOLUTE MAXIMUM RATINGS ....................................................................................................................................... 41
DC DIGITAL INPUT AND OUTPUT ELECTRICAL CHARACTERISTICS .................................................................................... 41
AC ELECTRICAL CHARACTERISTICS ............................................................................................................................... 41
POWER CONSUMPTION .................................................................................................................................................. 41
RECEIVER ELECTRICAL CHARACTERISTICS ..................................................................................................................... 42
E1 TRANSMITTER ELECTRICAL CHARACTERISTICS .......................................................................................................... 43
ORDERING INFORMATION.............................................................................................44
PACKAGE DIMENSIONS.................................................................................................44
REVISION HISTORY.......................................................................................................................................45
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
PIN DESCRIPTIONS
HOST MODE INTERFACE
SERIAL MICROPROCESSOR INTERFACE
NAME
PIN
TYPE
DESCRIPTION
CS
89
I
Chip Select Input
Active low signal. This signal enables the serial microprocessor interface by
pulling chip select "Low". The serial interface is disabled when the chip select
signal returns "High".
SCLK
90
I
Serial Clock Input
The serial clock input samples SDI on the rising edge and updates SDO on the
falling edge. See the Serial Microprocessor section of this datasheet for more
details.
SDI
92
I
Serial Data Input
The serial data input pin is used to supply an address and data string to program the internal registers within the device. See the Serial Microprocessor
section of this datasheet for more details.
SDO
91
O
Serial Data Output
The serial data output pin is used to retrieve the internal contents of a selected
register in readback mode. See the Microprocessor section of this datasheet
for more details.
Reset
28
I
Hardware Reset Input
Active low signal. When this pin is pulled "Low" for more than 10µS, all internal
registers and state machines are set to their default state.
NOTE: This pin must be pulled "High" to VDD for normal operation.
INT
100
O
Interrupt Output
Active low signal. This signal is asserted "Low" when a change in alarm status
occurs. Once the status registers have been read, the interrupt pin will return
"High". GIE (Global Interrupt Enable) must be set "High" in the appropriate
global register to enable interrupt generation.
NOTE: This pin is an open-drain output that requires an external 10KΩ pull-up
resistor.
HW/Host
81
I
Hardware / Host Mode Select Input
This pin is used to select the mode of operation. By default, the LIU is configured for Host mode. To select Hardware mode, this pin must be pulled "High".
NOTE: Internally pulled "Low" with a 50kΩ resistor.
5
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
RECEIVER SECTION
NAME
PIN
TYPE
DESCRIPTION
RLOS7
RLOS6
RLOS5
RLOS4
RLOS3
RLOS2
RLOS1
RLOS0
61
65
116
120
48
44
137
133
O
Receive Loss of Signal
When a receive loss of signal occurs, the RLOS pin will go "High" for a minimum of one RCLK cycle. RLOS will remain "High" until the loss of signal condition clears. See the Receive Loss of Signal section of this datasheet for
more details.
RCLK7
RCLK6
RCLK5
RCLK4
RCLK3
RCLK2
RCLK1
RCLK0
58
62
119
123
51
47
134
130
O
Receive Clock Output
RCLK is the recovered clock from the incoming data stream. If the incoming
signal is absent, RCLK maintains its timing by using an internal master clock
as its reference. RPOS/RNEG data can be updated on either edge of RCLK
selected by RCLKinv in the appropriate global register.
RPOS7
RPOS6
RPOS5
RPOS4
RPOS3
RPOS2
RPOS1
RPOS0
59
63
118
122
50
46
135
131
O
RPOS/RDATA Output
Receive digital output pin. In dual rail mode, this pin is the receive positive
data output. In single rail mode, this pin is the receive non-return to zero (NRZ)
data output.
RNEG/LCV7
RNEG/LCV6
RNEG/LCV5
RNEG/LCV4
RNEG/LCV3
RNEG/LCV2
RNEG/LCV1
RNEG/LCV0
60
64
117
121
49
45
136
132
O
RNEG/LCV Output
In dual rail mode, this pin is the receive negative data output. In single rail
mode, this pin is a Line Code Violation indicator. If a line code violation or a bipolar violation occur, the LCV pin will pull "High" for a minimum of one RCLK
cycle. LCV will remain "High" until there are no more violations.
NOTE: RCLKinv is a global setting that applies to all 8 channels.
6
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8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
RECEIVER SECTION
NAME
PIN
TYPE
DESCRIPTION
RTIP7
RTIP6
RTIP5
RTIP4
RTIP3
RTIP2
RTIP1
RTIP0
75
87
94
106
34
22
15
3
I
Receive Differential Tip Input
RTIP is the positive differential input from the line interface. Along with the
RRING signal, these pins should be coupled to a 1:1 transformer for proper
operation.
RRING7
RRING6
RRING5
RRING4
RRING3
RRING2
RRING1
RRING0
76
86
95
105
33
23
14
4
I
Receive Differential Ring Input
RRING is the negative differential input from the line interface. Along with the
RTIP signal, these pins should be coupled to a 1:1 transformer for proper operation.
TRANSMITTER SECTION
NAME
PIN
TYPE
DESCRIPTION
TxOE
9
I
Transmit Output Enable
Upon power up, the transmitters are tri-stated. Enabling the transmitters is
selected through the serial microprocessor interface by programming the
appropriate channel register if this pin is pulled "High". If the TxOE pin is
pulled "Low", all 8 transmitters are tri-stated.
NOTE:
TxOE is ideal for redundancy applications. See the Redundancy
Applications Section of this datasheet for more details. Internally
pulled "Low" with a 50KΩ resistor.
DMO7
DMO6
DMO5
DMO4
DMO3
DMO2
DMO1
DMO0
73
72
109
108
36
37
144
1
O
Driver Monitor Output
When no transmit output pulse is detected for more than 128 TCLK cycles, the
DMO pin will go "High" for a minimum of one TCLK cycle. DMO will remain
"High" until the transmitter sends a valid pulse.
TCLK7
TCLK6
TCLK5
TCLK4
TCLK3
TCLK2
TCLK1
TCLK0
69
66
115
112
40
43
138
141
I
Transmit Clock Input
TCLK is the input facility clock used to sample the incoming TPOS/TNEG data.
TPOS/TNEG data can be sampled on either edge of TCLK selected by TCLKinv in the appropriate global register.
NOTE: TCLKinv is a global setting that applies to all 8 channels.
7
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TRANSMITTER SECTION
NAME
PIN
TYPE
DESCRIPTION
TPOS7
TPOS6
TPOS5
TPOS4
TPOS3
TPOS2
TPOS1
TPOS0
70
67
114
111
39
42
139
142
I
TPOS/TDATA Input
Transmit digital input pin. In dual rail mode, this pin is the transmit positive
data input. In single rail mode, this pin is the transmit non-return to zero (NRZ)
data input.
TNEG7
TNEG6
TNEG5
TNEG4
TNEG3
TNEG2
TNEG1
TNEG0
71
68
113
110
38
41
140
143
I
Transmit Negative Data Input
In dual rail mode, this pin is the transmit negative data input. In single rail
mode, this pin can be tied to ground.
TTIP7
TTIP6
TTIP5
TTIP4
TTIP3
TTIP2
TTIP1
TTIP0
78
84
97
103
31
25
12
6
O
Transmit Differential Tip Output
TTIP is the positive differential output to the line interface. Along with the
TRING signal, these pins should be coupled to a 1:2 step up transformer for
proper operation.
TRING7
TRING6
TRING5
TRING4
TRING3
TRING2
TRING1
TRING0
80
82
99
101
29
27
10
8
O
Transmit Differential Ring Output
TRING is the negative differential output to the line interface. Along with the
TTIP signal, these pins should be coupled to a 1:2 step up transformer for
proper operation.
CONTROL FUNCTION
NAME
PIN
TYPE
DESCRIPTION
ICT
35
I
In Circuit Testing
When this pin is tied "Low", all output pins are forced to "High" impedance for
in circuit testing.
NOTE: Internally pulled "High" with a 50KΩ resistor.
MCLK
17
I
Master Clock Input
This pin is used as the internal reference to the LIU. This clock must be
2.048MHz +/-50ppm.
8
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
POWER AND GROUND (HOST AND HARDWARE MODES)
NAME
PIN
TYPE
DESCRIPTION
TVDD7
TVDD6
TVDD5
TVDD4
TVDD3
TVDD2
TVDD1
TVDD0
79
83
98
102
30
26
11
7
PWR
Transmit Analog Power Supply (3.3V ±5%)
TVDD can be shared with DVDD. However, it is recommended that TVDD be
isolated from the analog power supply RVDD. For best results, use an internal
power plane for isolation. If an internal power plane is not available, a ferrite
bead can be used. Each power supply pin should be bypassed to ground
through an external 0.1µF capacitor.
RVDD2
RVDD1
127
54
PWR
Receive Analog Power Supply (3.3V ±5%)
RVDD should not be shared with other power supplies. It is recommended that
RVDD be isolated from the digital power supply DVDD and the analog power
supply TVDD. For best results, use an internal power plane for isolation. If an
internal power plane is not available, a ferrite bead can be used. Each power
supply pin should be bypassed to ground through an external 0.1µF capacitor.
DVDD2
DVDD1
DVDDcore
129
52
93
PWR
Digital Power Supply (3.3V ±5%)
DVDD should be isolated from the analog power supplies except for TVDD.
For best results, use an internal power plane for isolation. If an internal power
plane is not available, a ferrite bead can be used. Every two DVDD power supply pins should be bypassed to ground through at least one 0.1µF capacitor.
AVDD
16
PWR
Analog Power Supply (3.3V ±5%)
AVDD should be isolated from the digital power supplies. For best results, use
an internal power plane for isolation. If an internal power plane is not available,
a ferrite bead can be used. Each power supply pin should be bypassed to
ground through at least one 0.1µF capacitor.
TGND7
TGND6
TGND5
TGND4
TGND3
TGND2
TGND1
TGND0
77
85
96
104
32
24
13
5
GND
Transmit Analog Ground
It’s recommended that all ground pins of this device be tied together.
RGND2
RGND1
126
55
GND
Receive Analog Ground
It’s recommended that all ground pins of this device be tied together.
DGND2
DGND1
DGNDcore
128
53
88
GND
Digital Ground
It’s recommended that all ground pins of this device be tied together.
AGND
18
GND
Analog Ground
It’s recommended that all ground pins of this device be tied together.
9
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
HARDWARE MODE INTERFACE
NAME
PIN
TYPE
DESCRIPTION
SR/DR
2
I
Single Rail / Dual Rail Select Input
This pin is used to select Single Rail or Dual Rail data formats. By default,
Dual Rail is selected. To select Single Rail mode, this pin must be pulled
"High". Once this pin is pulled "High", TNEGn/CODEn can be used to select
between AMI and HDB3 Encoding/Decoding.
NOTE: Internally pulled "Low" with a 50kΩ resistor.
TERSEL1
TERSEL0
125
124
I
Termination Impedance Select
TERSEL[1:0] are used to set the internal impedance of the LIU for the Receive
and Transmit paths.
"00" = 75Ω for Tx and "High-Z" for Rx
"01" = 120Ω for Tx and "High-Z" for Rx
"10" = 75Ω for Tx and Rx
"11" = 120Ω for Tx and Rx
TCLKinv
107
I
Transmit Clock Data
"Low" = TPOS/TNEG data is sampled on the falling edge of TCLK
"High" = TPOS/TNEG data is sampled on the rising edge of TCLK
NOTE: Internally pulled "Low" with a 50kΩ resistor.
RCLKinv
74
I
Receive Clock Data
"Low" = RPOS/RNEG data is updated on the rising edge of RCLK
"High" = RPOS/RNEG data is updated on the falling edge of RCLK
NOTE: Internally pulled "Low" with a 50kΩ resistor.
LBM1
LBM0
56
57
I
Loop Back Mode Select
LBM[1:0] are used to configure the LIU into diagnostic loopback modes. To
select the channel number, see pins CHLB[3:0].
LBM1
LBM0
Loopback Mode
0
0
No Loopback
0
1
Analog Loopback
1
0
Remote Loopback
1
1
Digital Loopback
NOTE: Internally pulled "Low" with a 50kΩ resistor.
JASEL1
JASEL0
20
21
I
Jitter Attenuator Select
JASEL[1:0] are used to configure the jitter attenuator into the Receive or
Transmit path for all eight channels.
JASEL1
JASEL0
JA Select Mode
0
0
JA Disabled
0
1
Transmit Path
1
0
Receive Path
1
1
JA Disabled
NOTE: Internally pulled "Low" with a 50kΩ resistor.
10
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
NAME
PIN
TYPE
DESCRIPTION
FIFOS
19
I
FIFO Bit Depth Select Input
This pin is used to select the depth of the FIFO. By default, the FIFO is set to
32-Bit. To select a 64-Bit FIFO depth, this pin must be pulled "High". To meet
TBR12/13 applications, the FIFO size must be set to 64-bit.
NOTE: Internally pulled "Low" with a 50kΩ resistor.
HW/Host
81
I
Same as Host Mode.
Reset
28
I
Same as Host Mode.
CHLB3
CHLB2
CHLB1
CHLB0
89
90
91
92
I
Channel Loop Back Select
CHLB[3:0] are used to select a particular channel or all eight channels simultaneously for Loop Back mode. See pins LBM[1:0] for selecting various types of
Loop Back diagnostics.
"0000" = Channel 0
"0001" = Channel 1
"0010" = Channel 2
"0011" = Channel 3
"0100" = Channel 4
"0101" = Channel 5
"0110" = Channel 6
"0111" = Channel 7
"1111" = All Eight Channels
NOTE: CHLB3 (Pin 89) is internally pulled "High" with a 50kΩ Resistor.
RLOS7
RLOS6
RLOS5
RLOS4
RLOS3
RLOS2
RLOS1
RLOS0
61
65
116
120
48
44
137
133
O
Same as Host Mode.
RCLK7
RCLK6
RCLK5
RCLK4
RCLK3
RCLK2
RCLK1
RCLK0
58
62
119
123
51
47
134
130
O
Same as Host Mode.
RPOS7
RPOS6
RPOS5
RPOS4
RPOS3
RPOS2
RPOS1
RPOS0
59
63
118
122
50
46
135
131
O
Same as Host Mode.
11
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
NAME
PIN
TYPE
DESCRIPTION
RNEG/LCV7
RNEG/LCV6
RNEG/LCV5
RNEG/LCV4
RNEG/LCV3
RNEG/LCV2
RNEG/LCV1
RNEG/LCV0
60
64
117
121
49
45
136
132
O
Same as Host Mode.
RTIP7
RTIP6
RTIP5
RTIP4
RTIP3
RTIP2
RTIP1
RTIP0
75
87
94
106
34
22
15
3
I
Same as Host Mode.
RRING7
RRING6
RRING5
RRING4
RRING3
RRING2
RRING1
RRING0
76
86
95
105
33
23
14
4
I
Same as Host Mode.
TXOE
9
I
Transmit Output Enable (Global Pin for All 8 Channels)
Upon power up, the transmitters are tri-stated. Enabling the transmitters is
controlled by pulling the TXOE hardware pin "High". If the TxOE pin is pulled
"Low", all 8 transmitters are tri-stated.
NOTE:
TxOE is ideal for redundancy applications. See the Redundancy
Applications Section of this datasheet for more details. Internally
pulled "Low" with a 50KΩ resistor.
DMO7
DMO6
DMO5
DMO4
DMO3
DMO2
DMO1
DMO0
73
72
109
108
36
37
144
1
O
Same as Host Mode.
TCLK7
TCLK6
TCLK5
TCLK4
TCLK3
TCLK2
TCLK1
TCLK0
69
66
115
112
40
43
138
141
I
Transmit Clock Input
TCLK is the input facility clock used to sample the incoming TPOS/TNEG data.
If TCLK is pulled "Low" for 16 MCLK cycles, the transmitter outputs at TTIP/
TRING are tri-stated. If TCLK is pulled "High" for 16 MCLK cycles, the transmitter outputs at TTIP/TRING will send an All Ones pattern. TPOS/TNEG data
can be sampled on either edge of TCLK selected by the TCLKinv pin.
NOTE: The TCLKinv pin is a global setting that applies to all 8 channels.
12
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
NAME
PIN
TYPE
DESCRIPTION
TPOS7
TPOS6
TPOS5
TPOS4
TPOS3
TPOS2
TPOS1
TPOS0
70
67
114
111
39
42
139
142
I
Same as Host Mode.
TNEG7/CODE7
TNEG6/CODE6
TNEG5/CODE5
TNEG4/CODE4
TNEG3/CODE3
TNEG2/CODE2
TNEG1/CODE1
TNEG0/CODE0
71
68
113
110
38
41
140
143
I
Transmit Negative Data / CODE Select Input
TTIP7
TTIP6
TTIP5
TTIP4
TTIP3
TTIP2
TTIP1
TTIP0
78
84
97
103
31
25
12
6
O
Same as Host Mode.
TRING7
TRING6
TRING5
TRING4
TRING3
TRING2
TRING1
TRING0
80
82
99
101
29
27
10
8
O
Same as Host Mode.
ICT
35
I
Same as Host Mode.
MCLK
17
I
Same as Host Mode.
TNEG has the same definition as Host Mode. However, in Hardware
mode and Single Rail Data Format, this pin is used to select between
AMI and HDB3 Encoder/Decoder. By default, HDB3 is selected. To
select AMI, this pin must be pulled "High".
NOTE: Internally pulled "Low" with a 50kΩ resistor.
13
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
1.0 RECEIVE PATH LINE INTERFACE
The receive path of the XRT83SL28 LIU consists of 8 independent E1 receivers. The following section
describes the complete receive path from RTIP/RRING inputs to RCLK/RPOS/RNEG outputs. A simplified
block diagram of the receive path is shown in Figure 4.
FIGURE 4. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE PATH LINE TERMINATION (RTIP/RRING)
RCLK
RPOS
RNEG
1.1
HDB3
Decoder
Rx Jitter
Attenuator
Clock & Data
Recovery
Peak Detector
& Slicer
RTIP
RRING
Internal Termination
The input stage of the receive path accepts standard E1 coaxial cable or E1 twisted pair inputs through RTIP
and RRING. The physical interface is optimized by placing the terminating impedance inside the LIU. This
allows one bill of materials for all modes of operation reducing the number of external components necessary
in system design. The receive termination impedance is selected by programming TERSEL[1:0] to match the
line impedance. The XRT83SL28 has the ability to switch the internal termination to "High" impedance for
redundancy applications. See Redundancy in the Applications Section of this datasheet. Selecting the internal
impedance is shown in Table 1. A typical connection diagram is shown in Figure 5.
TABLE 1: SELECTING THE INTERNAL IMPEDANCE
TERSEL[1:0]
RECEIVE TERMINATION
0h (00)
75Ω for Tx and "High-Z" for Rx
1h (01)
120Ω for Tx and "High-Z" for Rx
2h (10)
75Ω for Tx and Rx
3h (11)
120Ω for Tx and Rx
FIGURE 5. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION
XRT83SL28 LIU
RTIP
Receiver
Input
1:1
Line Interface E1
RRING
One Bill of Materials
Internal Impedance
14
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
1.2
Peak Detector/Data Slicer
In the receive path, the line signal is coupled into the RTIP and RRing pins via a 1:1 transformer and are
converted into digital pulses by an adaptive data slicer. Clock and data signals are recovered from the output of
the slicer with the help of a digital PLL that provides excellent jitter accommodation for high input jitter
tolerance.
1.3
Clock and Data Recovery
The receive clock (RCLK) is recovered by the clock and data recovery circuitry. An internal PLL locks on the
incoming data stream and outputs a clock that’s in phase with the incoming signal. In the absence of an
incoming signal, RCLK maintains its timing by using MCLK as its reference. The recovered data can be
updated on either edge of RCLK. By default, data is updated on the rising edge of RCLK. To update data on
the falling edge of RCLK, set RCLKinv to "1" in the appropriate global register. Figure 6 is a timing diagram of
the receive data updated on the rising edge of RCLK. Figure 7 is a timing diagram of the receive data updated
on the falling edge of RCLK. The timing specifications are shown in Table 2.
FIGURE 6. RECEIVE DATA UPDATED ON THE RISING EDGE OF RCLK
R C LK R
R DY
R C LK F
R C LK
RPOS
or
RNEG
R OH
FIGURE 7. RECEIVE DATA UPDATED ON THE FALLING EDGE OF RCLK
RCLKF
RDY
RCLKR
RCLK
RPOS
or
RNEG
ROH
TABLE 2: TIMING SPECIFICATIONS FOR RCLK/RPOS/RNEG
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
RCLK Duty Cycle
RCDU
45
50
55
%
Receive Data Setup Time
RSU
150
-
-
ns
Receive Data Hold Time
RHO
150
-
-
ns
RCLK to Data Delay
RDY
-
-
40
ns
15
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 2: TIMING SPECIFICATIONS FOR RCLK/RPOS/RNEG
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
RCLK Rise Time (10% to 90%)
with 25pF Loading
RCLKR
-
-
40
ns
RCLK Fall Time (90% to 10%)
with 25pF Loading
RCLKF
-
-
40
ns
NOTE: VDD=3.3V ±5%, TA=25°C, Unless Otherwise Specified
1.4
Receive Sensitivity
To meet short haul requirements, the XRT83SL28 can accept E1 signals that have been attenuated by 9dB of
cable loss in E1 mode. The test configuration for measuring the receive sensitivity is shown in Figure 8.
FIGURE 8. TEST CONFIGURATION FOR MEASURING RECEIVE SENSITIVITY
W&G ANT20
Tx
Network
Analyzer
Rx
Cable Loss
Rx
Tx
External Loopback
XRT83SL28
8-Channel
Short Haul LIU
E1 = PRBS 215 - 1
1.5
General Alarm Detection and Interrupt Generation
The receive path detects RLOS and AIS. These alarms can be individually masked to prevent the alarm from
triggering an interrupt. To enable interrupt generation, the Global Interrupt Enable (GIE) bit must be set "High"
in the appropriate global register. Any time a change in status occurs (if the alarms are enabled), the interrupt
pin will pull "Low" to indicate an alarm has occurred. Once the status registers have been read, the INT pin will
return "High". The status registers are Reset Upon Read (RUR).
NOTE: The interrupt pin is an Open-Drain output that requires a 10kΩ pull-up resistor.
16
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REV. 1.0.0
1.5.1
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
RLOS (Receiver Loss of Signal)
The XRT83SL28 supports both G.775 or ETSI-300-233 RLOS detection scheme.
In G.775 mode, RLOS is declared when the received signal is less than 320mV for 32 consecutive pulse
periods (typical). The device clears RLOS when the receive signal achieves 12.5% ones density with no more
than 15 consecutive zeros in a 32 bit sliding window and the signal level exceeds 550mV (typical).
In ETSI-300-233 mode the device declares RLOS when the input level drops below 320mV (typical) for more
than 2048 pulse periods (1msec). The device exits RLOS when the input signal exceeds 550mV (typical) and
has transitions for more than 32 pulse periods with 12.5% ones density with no more than 15 consecutive
zero’s in a 32 bit sliding window. ETSI-300-233 RLOSS detection method is only available in Host mode.
1.5.2
AIS (Alarm Indication Signal)
The XRT83SL28 adheres to ITU-T G.775 or ETSI-300-233 specifications for an all ones pattern detection by
programming the appropriate channel register. The alarm indication signal is set to "1" if an all ones pattern is
detected. In G.775 mode, AIS is defined as 2 or less zeros in 2 consecutive double frame (512-bit window)
periods. AIS will clear when the incoming signal has 3 or more zeros in the same time period. In ETSI-300-233
mode, AIS is defined as less than 3 zeros in a 512-bit window. AIS detection scheme per ESTI-300-233 is only
available in Host mode.
1.5.3
LCV (Line Code Violation Detection)
In HDB3 mode, the LCV pin will be set to "High" if the receiver detects excessive zero’s, bipolar violations or
HDB3 code violations. If the device is configured in AMI mode, any bipolar violations will cause the LCV pin to
go "High".
1.6
Receive Jitter Attenuator
The jitter attenuator can be configured in the receive path to reduce phase and frequency jitter in the recovered
clock. The jitter attenuator uses a data FIFO (First In First Out) with a programmable depth of 32-bit or 64-bit. If
the LIU is used for line synchronization (loop timing systems), the JA should be enabled. When the Read and
Write pointers of the FIFO are within 2-Bits of over-flowing or under-flowing, the bandwidth of the jitter
attenuator is widened to track the short term input jitter, thereby avoiding data corruption. When this condition
occurs, the jitter attenuator will not attenuate input jitter until the Read/Write pointer’s position is outside the 2Bit window. The bandwidth is set to 2Hz when the JA is configured in the Receive or Transmit path. The JA has
a typical clock delay equal to ½ of the FIFO bit depth.
NOTE: If the LIU is used in a multiplexer/mapper application where stuffing bits are typically removed, the JA can be
configured in the transmit path to smooth out the gapped clock. See the Transmit Section of this datasheet.
17
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
1.7
REV. 1.0.0
HDB3 Decoder
In single rail mode, RPOS is the output of decoded AMI or HDB3 signals and RNEG is the LCV output. HDB3
data is defined as any block of 4 successive zeros replaced with OOOV or BOOV, so that two successive V
pulses are of opposite polarity to acheive zero DC offsey. If the HDB3 decoder is selected, the receive path
removes the V and B pulses so that the original data is output to RPOS.
1.8
ARAOS (Automatic Receive All Ones)
The XRT83SL28 has the ability to send an All Ones signal to RPOS if ARAOS is enabled in the appropriate
channel register. If ARAOS is enabled and an RLOS condition occurs, the Receiver outputs will generate a
single rail All Ones pattern. When RLOS clears, the All Ones pattern ends and the Receive path returns to
normal operation. For TAOS in the transmit direction, see the Transmit Section of this datasheet. A simplified
block diagram of the ATAOS function is shown in Figure 9.
FIGURE 9. SIMPLIFIED BLOCK DIAGRAM OF THE ARAOS FUNCTION
RPOS
Rx
RNEG
TAOS
ARAOS
RLOS
1.9
RPOS/RNEG/RCLK
The digital output data can be programmed to either single rail or dual rail formats. Figure 10 is a timing
diagram of a repeating "0011" pattern in single-rail mode. Figure 11 is a timing diagram of the same fixed
pattern in dual rail mode.
FIGURE 10. SINGLE RAIL MODE WITH A FIXED REPEATING "0011" PATTERN
RCLK
RPOS
0
0
1
18
1
0
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
FIGURE 11. DUAL RAIL MODE WITH A FIXED REPEATING "0011" PATTERN
RCLK
RPOS
RNEG
0
0
1
0
1
19
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.0 TRANSMIT PATH LINE INTERFACE
The transmit path of the XRT83SL28 LIU consists of 8 independent E1 transmitters. The following section
describes the complete transmit path from TCLK/TPOS/TNEG inputs to TTIP/TRING outputs. A simplified
block diagram of the transmit path is shown in Figure 12.
FIGURE 12. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT PATH
TCLK
TPOS
TNEG
2.1
HDB3
Encoder
Tx Jitter
Attenuator
TTIP
Timing
Control
Tx Pulse Shaper
Line Driver
TRING
TCLK/TPOS/TNEG Digital Inputs
In dual rail mode, TPOS and TNEG are the digital inputs for the transmit path. In single rail mode, TNEG can
be tied to ground unless Hardware mode is selected (see the Hardware Pin Description). The XRT83SL28 can
be programmed to sample the inputs on either edge of TCLK. By default, data is sampled on the falling edge of
TCLK. To sample data on the rising edge of TCLK, set TCLKinv to "1" in the appropriate global register.
Figure 13 is a timing diagram of the transmit input data sampled on the falling edge of TCLK. Figure 14 is a
timing diagram of the transmit input data sampled on the rising edge of TCLK. The timing specifications are
shown in Table 3.
FIGURE 13. TRANSMIT DATA SAMPLED ON FALLING EDGE OF TCLK
TCLKR
TCLKF
TCLK
TPOS
or
TNEG
TSU
THO
FIGURE 14. TRANSMIT DATA SAMPLED ON RISING EDGE OF TCLK
TCLKF
TCLK
TPOS
or
TNEG
TSU
THO
20
TCLKR
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 3: TIMING SPECIFICATIONS FOR TCLK/TPOS/TNEG
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
TCLK Duty Cycle
TCDU
30
50
70
%
Transmit Data Setup Time
TSU
50
-
-
ns
Transmit Data Hold Time
THO
30
-
-
ns
TCLK Rise Time (10% to 90%)
TCLKR
-
-
40
ns
TCLK Fall Time (90% to 10%)
TCLKF
-
-
40
ns
NOTE: VDD=3.3V ±5%, TA=25°C, Unless Otherwise Specified
2.2
HDB3 Encoder
In single rail mode, the LIU can encode the TPOS input signal to AMI or HDB3 data. If HDB3 encoding is
selected, any sequence with four or more consecutive zeros in the input will be replaced with 000V or B00V,
where "B" indicates a pulse conforming to the bipolar rule and "V" representing a pulse violating the rule. An
example of HDB3 encoding is shown in Table 4.
TABLE 4: EXAMPLES OF HDB3 ENCODING
NUMBER OF PULSES BEFORE
NEXT 4 ZEROS
Input
2.3
0000
HDB3 (Case 1)
Odd
000V
HDB3 (Case 2)
Even
B00V
Transmit Jitter Attenuator
The XRT83SL28 LIU is ideal for multiplexer or mapper applications where the network data crosses multiple
timing domains. As the higher data rates are de-multiplexed to E1 data, stuffing bits are typically removed
which can leave gaps in the incoming data stream. The JA can be configured in the transmit path with a 32-Bit
or 64-Bit FIFO that is used to smooth the gapped clock into a steady E1 output. The maximum gap width the
JA in the Transmit path can tolerate is shown in Table 5.
TABLE 5: MAXIMUM GAP WIDTH FOR MULTIPLEXER/MAPPER APPLICATIONS
FIFO DEPTH
MAXIMUM GAP WIDTH
32-Bit
20 UI
64-Bit
50 UI
NOTE: If the LIU is used in a loop timing system, the JA should be configured in the receive path. See the Receive Section
of this datasheet.
21
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
2.4
REV. 1.0.0
TAOS (Transmit All Ones)
The XRT83SL28 has the ability to transmit all ones on a per channel basis by programming the appropriate
channel register. If TAOS is enabled, the Transmitter outputs will generate an All Ones pattern regardless of
the Transmit Input data. The Remote Loop Back mode has priority over TAOS. Figure 15 is a diagram showing
the all ones signal at TTIP and TRING.
FIGURE 15. TAOS (TRANSMIT ALL ONES)ATAOS (AUTOMATIC TRANSMIT ALL ONES)
1
1
1
TAOS
2.5
ATAOS (Automatic Transmit All Ones)
Unlike TAOS, ATAOS is used to generate an All Ones signal only when an RLOS condition occurs. If ATAOS is
enabled, any channel that experiences an RLOS condition will automatically cause the transmitter on that
channel to send an all ones pattern to the line. When RLOS clears, the All Ones pattern ends and the Transmit
path returns to normal operation. For TAOS on the receive output pins, see ARAOS in the Receive Section of
this datasheet. A simplified block diagram of the ATAOS function is shown in Figure 16.
FIGURE 16. SIMPLIFIED BLOCK DIAGRAM OF THE ATAOS FUNCTION
Tx
TTIP
TRING
TAOS
ATAOS
RLOS
2.6
Transmitter Power down in Hardware mode
In Hardware mode, if TCLK is pulled "Low" for 16 MCLK cycles the transmitter outputs at TTIP/TRING are tristated. If TCLK is pulled "High" for 16 MCLK cycles the transmitter will send an All Ones signal to the line,
using MCLK as reference.
2.7
DMO (Driver Monitor Output)
The driver monitor circuit is used to detect transmit driver failures by monitoring the activities at TTIP/TRING
outputs. Driver failure may be caused by a short circuit in the primary transformer or system problems at the
transmit inputs. If the transmitter of a channel has no output for more than 128 TCLK cycles, DMO goes "High"
until a valid transmit pulse is detected. If the DMO interrupt is enabled, the change in status of DMO will cause
the interrupt pin to go "Low". Once the status register is read, the interrupt pin will return "High" and the status
register will be reset (RUR).
22
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.8
Line Termination (TTIP/TRING)
The output stage of the transmit path generates standard bipolar signals to the line for both E1 (75 Ohm)
coaxial cable and E1 (120 Ohm) twisted pair. The XRT83L28 has built-in output impedance matching for both
75 Ohm and 120 Ohm operations. This eliminates the need to change any external components while
switching from 75 Ohm to 120 Ohm operation. The transmitter interface only requires one 0.68µF DC blocking
capacitor with a 1:2 transformer as shown in Figure 17.
FIGURE 17. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION
XRT83SL28 LIU
TTIP
Transmitter
Output
1:2
C=0.68uF
TRING
One Bill of Materials
Internal Impedance
23
Line Interface E1
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
3.0 E1 APPLICATIONS
This applications section describes common E1 system considerations along with references to application
notes available for reference where applicable.
3.1
Loopback Diagnostics
The XRT83SL28 supports several loopback modes for diagnostic testing. The following section describes the
local analog loopback, remote loopback, and digital loopback.
3.1.1
Local Analog Loopback
With local analog loopback activated, the transmit output data at TTIP/TRING is internally looped back to the
analog inputs at RTIP/RRING. External inputs at RTIP/RRING are ignored while valid transmit output data
continues to be sent to the line. A simplified block diagram of local analog loopback is shown in Figure 18.
FIGURE 18. SIMPLIFIED BLOCK DIAGRAM OF LOCAL ANALOG LOOPBACK
TAOS
TCLK
TPOS
TNEG
Encoder
JA
Timing
Control
RCLK
RPOS
RNEG
Decoder
JA
Data and
Clock
Recovery
TTIP
TRING
Tx
RTIP
RRING
Rx
NOTE: TAOS takes priority over the transmit input data at TPOS/TNEG.
3.1.2
Remote Loopback
With remote loopback activated, the receive input data at RTIP/RRING is internally looped back to the transmit
output data at TTIP/TRING. The transmit input data at TCLK/TPOS/TNEG are ignored while valid receive
output data continues to be sent to the system. A simplified block diagram of remote loopback is shown in
Figure 19.
FIGURE 19. SIMPLIFIED BLOCK DIAGRAM OF REMOTE LOOPBACK
TAOS
TCLK
TPOS
TNEG
Encoder
JA
Timing
Control
RCLK
RPOS
RNEG
Decoder
JA
Data and
Clock
Recovery
NOTE: Remote Loop Back takes priority over TAOS.
24
TTIP
TRING
Tx
Rx
RTIP
RRING
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
3.1.3
Digital Loopback
With digital loopback activated, the transmit input data at TCLK/TPOS/TNEG is looped back to the receive
output data at RCLK/RPOS/RNEG. The receive input data at RTIP/RRING is ignored while valid transmit
output data continues to be sent to the line. A simplified block diagram of digital loopback is shown in
Figure 20.
FIGURE 20. SIMPLIFIED BLOCK DIAGRAM OF DIGITAL LOOPBACK
TAOS
TCLK
TPOS
TNEG
Encoder
JA
Timing
Control
RCLK
RPOS
RNEG
Decoder
JA
Data and
Clock
Recovery
25
TTIP
TRING
Tx
Rx
RTIP
RRING
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
3.2
REV. 1.0.0
Line Card Redundancy
Telecommunication system design requires signal integrity and reliability. When an E1 primary line card has a
failure, it must be swapped with a backup line card while maintaining connectivity to a backplane without losing
data. System designers can achieve this by implementing common redundancy schemes with the
XRT83SL28 LIU. EXAR offers features that are tailored to redundancy applications while reducing the number
of components and providing system designers with solid reference designs.
RLOS and DMO
If an RLOS or DMO condition occurs, the XRT83SL28 reports the alarm to the individual status registers on a
per channel basis. However, for redundancy applications, RLOS and DMO pins can be used to initiate an
automatic switch to the back up card.
Typical Redundancy Schemes
• 1:1 One backup card for every primary card (Facility Protection)
• 1+1 One backup card for every primary card (Line Protection)
• ·N+1 One backup card for N primary cards
3.2.1
1:1 and 1+1 Redundancy Without Relays
The 1:1 facility protection and 1+1 line protection have one backup card for every primary card. When using
1:1 or 1+1 redundancy, the backup card has its transmitters tri-stated and its receivers in high impedance. This
eliminates the need for external relays and provides one bill of materials for all interface modes of operation.
For 1+1 line protection, the receiver inputs on the backup card have the ability to monitor the line for bit errors
while in high impedance. The transmit and receive sections of the LIU device are described separately.
3.2.2
Transmit Interface with 1:1 and 1+1 Redundancy
The transmitters on the backup card should be tri-stated. Select the appropriate impedance for the desired
mode of operation, E1 75Ω or 120Ω. A 0.68uF capacitor is used in series with TTIP for blocking DC bias. See
Figure 21. for a simplified block diagram of the transmit section for a 1:1 and 1+1 redundancy.
FIGURE 21. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR 1:1 AND 1+1 REDUNDANCY
Backplane Interface
Primary Card
XRT83SL28
1:2
Tx
0.68uF
E1 Line
Internal Impedance
Backup Card
XRT83SL28
1:2
Tx
0.68uF
Internal Impedance
26
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8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
3.2.3
Receive Interface with 1:1 and 1+1 Redundancy
The receivers on the backup card should be programmed for "High" impedance. Since there is no external
resistor in the circuit, the receivers on the backup card will not load down the line interface. This key design
feature eliminates the need for relays and provides one bill of materials for all interface modes of operation.
Select the impedance for the desired mode of operation, E1 75Ω or 120Ω. To swap the primary card, set the
backup card to internal impedance, then the primary card to "High" impedance. See Figure 22. for a simplified
block diagram of the receive section for a 1:1 redundancy scheme.
FIGURE 22. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR 1:1 AND 1+1 REDUNDANCY
Backplane Interface
Primary Card
XRT83SL28
1:1
E1 Line
Rx
Internal Impedance
Backup Card
XRT83SL28
1:1
Rx
"High" Impedance
3.2.4
N+1 Redundancy Using External Relays
N+1 redundancy has one backup card for N primary cards. Due to impedance mismatch and signal
contention, external relays are necessary when using this redundancy scheme. The relays create complete
isolation between the primary cards and the backup card. This allows all transmitters and receivers on the
primary cards to be configured in internal impedance, providing one bill of materials for all interface modes of
operation. The transmit and receive sections of the LIU device are described separately.
27
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
3.2.5
REV. 1.0.0
Transmit Interface with N+1 Redundancy
For N+1 redundancy, the transmitters on all cards can be programmed for internal impedance. The
transmitters on the backup card do not have to be tri-stated. To swap the primary card, close the desired
relays. A 0.68uF capacitor is used in series with TTIP for blocking DC bias. See Figure 23 for a simplified
block diagram of the transmit section for an N+1 redundancy scheme.
FIGURE 23. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR N+1 REDUNDANCY
Backplane Interface
Line Interface Card
Primary Card
XRT83SL28
1:2
Tx
0.68uF
E1 Line
Internal Impedance
XRT83SL28
Primary Card
1:2
Tx
0.68uF
E1 Line
Internal Impedance
Primary Card
XRT83SL28
1:2
Tx
0.68uF
E1 Line
Internal Impedance
Backup Card
XRT83SL28
Tx
0.68uF
Internal Impedance
28
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
3.2.6
Receive Interface with N+1 Redundancy
For N+1 redundancy, the receivers on all cards can be programmed for internal impedance. The receivers on
the backup card do not have to be tri-stated. To swap the primary card, close the desired relays. See Figure
Figure 24 for a simplified block diagram of the receive section for an N+1 redundancy scheme.
FIGURE 24. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR N+1 REDUNDANCY
Backplane Interface
Primary Card
Line Interface Card
XRT83SL28
1:1
Rx
E1 Line
Internal Impedance
Primary Card
XRT83SL28
1:1
Rx
E1 Line
Internal Impedance
Primary Card
XRT83SL28
1:1
Rx
E1 Line
Internal Impedance
Backup Card
XRT83SL28
Rx
Internal Impedance
29
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
3.3
REV. 1.0.0
Power Failure Protection
For 1:1 or 1+1 line card redundancy in E1 applications, power failure could cause a line card to change the
characteristics of the line impedance, causing a degradation in system performance. The XRT83SL28 is
designed to ensure reliability during power failures. The LIU has patented high impedance circuits that allow
the receiver inputs and the transmitter outputs to be in "High" impedance when the LIU experiences a power
failure or when the LIU is powered off.
NOTE: For power failure protection, a transformer must be used to couple to the line interface. See the TAN-56 application
note for more details.
3.4
Overvoltage and Overcurrent Protection
Physical layer devices such as LIUs that interface to telecommunications lines are exposed to overvoltage
transients posed by environmental threats. An Overvoltage transient is a pulse of energy concentrated over a
small period of time, usually under a few milliseconds. These pulses are random and exceed the operating
conditions of CMOS transceiver ICs. Electronic equipment connecting to data lines are susceptible to many
forms of overvoltage transients such as lightning, AC power faults and electrostatic discharge (ESD). There
are three important standards when designing a telecommunications system to withstand overvoltage
transients.
• UL1950 and FCC Part 68
• Telcordia (Bellcore) GR-1089
• ITU-T K.20, K.21 and K.41
NOTE: For a reference design and performance, see the TAN-54 application note for more details.
3.5
Non-Intrusive Monitoring
In non-intrusive monitoring applications, the transmitters are shut off by setting TxON "Low". The receivers
must be actively receiving data without interfering with the line impedance. The XRT83SL28’s internal
termination ensures that the line termination meets E1 specifications for 75Ω or 120Ω while monitoring the data
stream. System integrity is maintained by placing the non-intrusive receiver in "High" impedance, equivalent to
that of a 1+1 redundancy application. A simplified block diagram of non-intrusive monitoring is shown in
Figure 25.
FIGURE 25. SIMPLIFIED BLOCK DIAGRAM OF A NON-INTRUSIVE MONITORING APPLICATION
XRT83SL28
Data Traffic
Line Card Transceiver
Node
XRT83SL28
Non-Intrusive Receiver
30
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
4.0 SERIAL MICROPROCESSOR INTERFACE BLOCK
The serial microprocessor uses a standard 3-pin serial port with CS, SCLK, and SDI for programming the LIU.
Optional pins such as SDO, INT, and RESET allow the ability to read back contents of the registers, monitor
the LIU via an interrupt pin, and reset the LIU to its default configuration by pulling reset "Low" for more than
10µS. A simplified block diagram of the Serial Microprocessor is shown in Figure 26.
FIGURE 26. SIMPLIFIED BLOCK DIAGRAM OF THE SERIAL MICROPROCESSOR INTERFACE
SDO
CS
SCLK
INT
SDI
Serial
Microprocessor
Interface
HW/Host
RESET
4.1
Serial Timing Information
The serial port requires 16 bits of data applied to the SDI (Serial Data Input) pin. The Serial Microprocessor
samples SDI on the rising edge of SCLK (Serial Clock Input). The data is not latched into the device until all 16
bits of serial data have been sampled. A timing diagram of the Serial Microprocessor is shown in Figure 27.
FIGURE 27. TIMING DIAGRAM FOR THE SERIAL MICROPROCESSOR INTERFACE
CS
25nS
50nS
SCLK
1
SDI
R/W
SDO
2
A0
3
A1
4
A2
5
A3
6
A4
7
A5
9
8
X
High-Z
31
10
11
12
13
14
15
16
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
High-Z
�XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
4.2
xr
REV. 1.0.0
16-Bit Serial Data Input Description
The serial data input is sampled on the rising edge of SCLK. In read-back mode, the serial data output is
updated on the falling edge of SCLK. The serial data must be applied to the LIU LSB first. The 16 bits of serial
data are described below.
4.2.1
R/W (SCLK1)
The first serial bit applied to the LIU informs the microprocessor that a Read or Write operation is desired. If the
R/W bit is set to “0”, the microprocessor is configured for a Write operation. If the R/W bit is set to “1”, the
microprocessor is configured for a Read operation.
4.2.2
A[5:0] (SCLK2 - SCLK7)
The next 6 SCLK cycles are used to provide the address to which a Read or Write operation will occur. A0
(LSB) must be sent to the LIU first followed by A1 and so forth until all 6 address bits have been sampled by
SCLK.
4.2.3
X (Dummy Bit SCLK8)
The dummy bit sampled by SCLK8 is used to allow sufficient time for the serial data output pin to update data
if the read-back mode is selected by setting R/W = “1”. Therefore, the state of this bit is ignored and can hold
either “0” or “1” during both Read and Write operations.
4.2.4
D[7:0] (SCLK9 - SCLK16)
The next 8 SCLK cycles are used to provide the data to be written into the internal register chosen by the
address bits. D0 (LSB) must be sent to the LIU first followed by D1 and so forth until all 8 data bits have been
sampled by SCLK. Once 16 SCLK cycles have been complete, the LIU holds the data until CS is pulled “High”
whereby, the serial microprocessor latches the data into the selected internal register.
4.3
8-Bit Serial Data Output Description
The serial data output is updated on the falling edge of SCLK9 - SCLK16 if R/W is set to “1”. D0 (LSB) is
provided on SCLK9 to the SDO pin first followed by D1 and so forth until all 8 data bits have been updated. The
SDO pin allows the user to read the contents stored in individual registers by providing the desired address on
the SDI pin during the Read cycle.
32
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8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 6: MICROPROCESSOR REGISTER DESCRIPTION
REG
ADDR TYPE
D7
D6
D5
D4
D3
D2
D1
D0
RCLKinv
TCLKinv
FIFO
JASEL1
JASEL0
Global Control Register for All 8 Channels (0x00h)
0
0x00
R/W
GIE
SR/DR
CODE
1
0x01
RO
Revision ID (See Bit Description)
2
0x02
RO
Device ID (See Bit Description)
3
0x03
R/W
For Internal Use Only
TSTEN
Channel 0 Control Register (0x04h - 0x07h)
4
0x04
R/W
Reserved
RLAM0
ARAOS0
ATAOS0
TAOS0
TXOE0
TERSEL1
TERSEL0
5
0x05
R/W
Reserved
SRESET0
AISIE0
DMOIE0
RLOSIE0
Reserved
LB1
LB0
6
0x06
RUR
Reserved
Reserved
AISI0
DMOI0
RLOSI0
Reserved
Reserved
Reserved
7
0x07
RO
Reserved
Reserved
AISS0
DMOS0
RLOSS0
Reserved
Reserved
Reserved
Channel 1 Control Register (0x08h - 0x0Bh)
8
0x08
RO
Reserved
RLAM1
ARAOS1
ATAOS1
TAOS1
TXOE1
TERSEL1
TERSEL0
9
0x09
R/W
Reserved
SRESET1
AISIE1
DMOIE1
RLOSIE1
Reserved
LB1
LB0
10
0x0A
RUR
Reserved
Reserved
AISI1
DMOI1
RLOSI1
Reserved
Reserved
Reserved
11
0x0B
RO
Reserved
Reserved
AISS1
DMOS1
RLOSS1
Reserved
Reserved
Reserved
Channel 2 Control Register (0x0Ch - 0x0Fh)
12
0x0C
R/W
Reserved
RLAM2
ARAOS2
ATAOS2
TAOS2
TXOE2
TERSEL1
TERSEL0
13
0x0D
R/W
Reserved
SRESET2
AISIE2
DMOIE2
RLOSIE2
Reserved
LB1
LB0
14
0x0E
RUR
Reserved
Reserved
AISI2
DMOI2
RLOSI2
Reserved
Reserved
Reserved
15
0x0F
RO
Reserved
Reserved
AISS2
DMOS2
RLOSS2
Reserved
Reserved
Reserved
Channel 3 Control Register (0x10h - 0x13h)
16
0x10
R/W
Reserved
RLAM3
ARAOS3
ATAOS3
TAOS3
TXOE3
TERSEL1
TERSEL0
17
0X11
R/W
Reserved
SRESET3
AISIE3
DMOIE3
RLOSIE3
Reserved
LB1
LB0
18
0x12
RUR
Reserved
Reserved
AISI3
DMOI3
RLOSI3
Reserved
Reserved
Reserved
19
0x13
RO
Reserved
Reserved
AISS3
DMOS3
RLOSS3
Reserved
Reserved
Reserved
Channel 4 Control Register (0x14h - 0x17h)\
20
0x14
R/W
Reserved
RLAM4
ARAOS4
ATAOS4
TAOS4
TXOE4
TERSEL1
TERSEL0
21
0x15
R/W
Reserved
SRESET4
AISIE4
DMOIE4
RLOSIE4
Reserved
LB1
LB0
22
0x16
RUR
Reserved
Reserved
AISI4
DMOI4
RLOSI4
Reserved
Reserved
Reserved
23
0x17
RO
Reserved
Reserved
AISS4
DMOS4
RLOSS4
Reserved
Reserved
Reserved
Channel 5 Control Register (0x18h - 0x1Bh)
24
0x18
R/W
Reserved
RLAM3
ARAOS5
ATAOS5
TAOS5
TXOE5
TERSEL1
TERSEL0
25
0x19
R/W
Reserved
SRESET5
AISIE5
DMOIE5
RLOSIE5
Reserved
LB1
LB0
26
0x1A
RUR
Reserved
Reserved
AISI5
DMOI5
RLOSI5
Reserved
Reserved
Reserved
27
0X1B
RO
Reserved
Reserved
AISS5
DMOS5
RLOSS5
Reserved
Reserved
Reserved
33
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 6: MICROPROCESSOR REGISTER DESCRIPTION
REG
ADDR TYPE
D7
D6
D5
D4
D3
D2
D1
D0
Channel 6 Control Register (0x1Ch - 0x1Fh)
28
0x1C
R/W
Reserved
RLAM6
ARAOS6
ATAOS6
TAOS6
TXOE6
TERSEL1
TERSEL0
29
0x1D
R/W
Reserved
SRESET6
AISIE6
DMOIE6
RLOSIE6
Reserved
LB1
LB0
30
0x1E
RUR
Reserved
Reserved
AISI6
DMOI6
RLOSI6
Reserved
Reserved
Reserved
31
0X1F
RO
Reserved
Reserved
AISS6
DMOS6
RLOSS6
Reserved
Reserved
Reserved
Channel 7 Control Register (0x20h - 0x23h)
32
0x20
R/W
Reserved
RLAM7
ARAOS7
ATAOS7
TAOS7
TXOE7
TERSEL1
TERSEL0
33
0x21
R/W
Reserved
SRESET7
AISIE7
DMOIE7
RLOSIE7
Reserved
LB1
LB0
34
0x22
RUR
Reserved
Reserved
AISI7
DMOI7
RLOSI7
Reserved
Reserved
Reserved
35
0X23
RO
Reserved
Reserved
AISS7
DMOS7
RLOSS7
Reserved
Reserved
Reserved
34
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8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 7: MICROPROCESSOR REGISTER 0X00H BIT DESCRIPTION
GLOBAL CONTROL REGISTER FOR ALL 8 CHANNELS (0X00H)
BIT
NAME
FUNCTION
D7
GIE
Global Interrupt Enable
The global interrupt enable is used to enable/disable all interrupt
activity for all 8 channels. This bit must be set "High" for the interrupt pin to operate.
Register
Type
Default
Value
(HW reset)
R/W
0
R/W
0
R/W
0
"0" = Disable all interrupt generation
"1" = Enable interrupt generation to the individual channel registers
D6
SR/DR
Single Rail / Dual Rail Select
This bit is used to configure the receive outputs and transmit inputs
to single rail or dual rail data formats.
"0" = Dual Rail
"1" = Single Rail
D5
CODE
Encoding / Decoding Select (Single Rail Mode Only)
This bit is used to select between AMI or HDB3.
"0" = HDB3
"1" = AMI
D4
RCLKinv
Receiver Clock Data
"0" = RPOS/RNEG data is updated on the rising edge of RCLK
"1" = RPOS/RNEG data is updated on the falling edge of RCLK
R/W
0
D3
TCLKinv
Transmitter Clock Data
"0" = TPOS/TNEG data is sampled on the falling edge of TCLK
"1" = TPOS/TNEG data is sampled on the rising edge of TCLK
R/W
0
D2
FIFOS
FIFO Depth Select
The FIFO depth select is used to configure the part for a 32-bit or
64-bit FIFO (Within the Jitter Attenuator Block). The delay of the
FIFO is typically equal to ½ the FIFO depth.
R/W
0
R/W
0
0
"0" = 32-bit FIFO
"1" = 64-bit FIFO
D1
D0
JASEL1
JASEL0
Jitter Attenuator Select
These bits are used to configure the Jitter Attenuator into the
Receive or Transmit path.
"00" = Disabled
"01" = Transmit Path
"10" = Receive Path
"11" = Disabled
35
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 8: MICROPROCESSOR REGISTER 0X01H BIT DESCRIPTION
REVISION "ID" REGISTER (0X01H)
BIT
NAME
FUNCTION
D7
D6
D5
D4
D3
D2
D1
D0
Revision
"ID"
The revision "ID" of the XRT83SL28 LIU is used to enable software
to identify which revision of silicon is currently being tested. The
revision "ID" for the first revision of silicon (Revision A) will be
0x01h.
Register
Type
Default
Value
(HW reset)
RO
0
0
0
0
0
0
0
1
Register
Type
Default
Value
(HW reset)
RO
1
1
1
1
0
1
1
1
TABLE 9: MICROPROCESSOR REGISTER 0X02H BIT DESCRIPTION
DEVICE "ID" REGISTER (0X02H)
BIT
D7
D6
D5
D4
D3
D2
D1
D0
NAME
FUNCTION
Device "ID" The device "ID" of the XRT83SL28 LIU is 0xF7h. Along with the
revision "ID", the device "ID" is used to enable software to identify
the silicon adding flexibility for system control and debug.
TABLE 10: MICROPROCESSOR REGISTER BIT DESCRIPTION
CHANNEL CONTROL REGISTER (0X04H, 0X08H, 0X0CH, 0X10H, 0X14H, 0X18H, 0X1CH, 0X20H)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
D6
RLAM_n
RLOS/AIS Mode Select
This bit is used to select the industry standard for declaring / clearing RLOS and AIS functionality. See the Receive Path Line Interface section of this datasheet.
"0" = ITU G.775
"1" = ETSI300233
36
Register
Type
Default
Value
(HW reset)
X
X
R/W
0
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 10: MICROPROCESSOR REGISTER BIT DESCRIPTION
CHANNEL CONTROL REGISTER (0X04H, 0X08H, 0X0CH, 0X10H, 0X14H, 0X18H, 0X1CH, 0X20H)
BIT
NAME
FUNCTION
D5
ARAOS_n
Automatic Receive All Ones
If ARAOS_n is selected, an all ones pattern will be sent to the
RPOS/RNEG outputs if the channel experiences an RLOS condition. If RLOS does not occur, ARAOS_n will remain inactive.
Register
Type
Default
Value
(HW reset)
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
0
"0" = Disabled
"1" = Enabled
D4
ATAOS_n
Automatic Transmit All Ones
If ATAOS_n is selected, an all ones pattern will be transmitted from
TTIP/TRING if the channel experiences an RLOS condition. If
RLOS does not occur, ATAOS_n will remain inactive.
"0" = Disabled
"1" = Enabled
D3
TAOS_n
Transmit All Ones
If TAOS_n is selected, an all ones pattern will be transmitted from
TTIP/TRING if the transmitter is turned on. Remote Loop Back
has priority over TAOS.
"0" = Disabled
"1" = Enabled
D2
TXOE_n
Transmit Output Enable
Upon power up, the tranmitters are tri-stated. This bit is used to
enable the transmitter for this channel if the TxOE pin is pulled
"High". If the TxOE pin is pulled "Low", all 8 transmitters are tristated.
"0" = Transmitter is disabled
"1" = Transmitter is enabled if TxOE pin is pulled "High"
D1
D0
TERSEL1
TERSEL0
Receive Line Impedance Select
TERSEL[1:0] are used to select the internal line impedance.
"00" = 75Ω for Tx and "High-Z" for Rx
"01" = 120Ω for Tx and "High-Z" for Rx
"10" = 75Ω for Tx and Rx
"11" = 120Ω for Tx and Rx
37
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 11: MICROPROCESSOR REGISTER BIT DESCRIPTION
CHANNEL CONTROL REGISTER (0X05H, 0X09H, 0X0DH, 0X11H, 0X15H, 0X19H, 0X1DH, 0X21H)
BIT
NAME
D7
Reserved
D6
FUNCTION
This Register Bit is Not Used
SRESET_n Software Reset
By setting this bit to "1" for more than 10µS, the individual channel
is reset to its default register configuration and all state machines
are internally reset.
Register
Type
Default
Value
(HW reset)
X
X
R/W
0
"0" = ITU G.775
"1" = ETSI300233
D5
AISIE_n
Alarm Indication Signal Interrupt Enable
"0" = Masks the AIS interrupt generation
"1" = Enables Interrupt generation
R/W
0
D4
DMOIE_n
Driver Monitor Output Interrupt Enable
"0" = Masks the DMO interrupt generation
"1" = Enables Interrupt generation
R/W
0
D3
RLOSIE_n Receiver Loss of Signal Interrupt Enable
"0" = Masks the RLOS interrupt generation
"1" = Enables Interrupt generation
R/W
0
D2
Reserved
X
X
D1
D0
LB1
LB0
R/W
0
This Register Bit is Not Used
Loop Back Select
These bits are used to configure the channel in one of three loopback modes. For additional information on loopback modes, see
the Application Section of this datasheet.
LB1
LB0
Loopback Mode
0
0
No Loopback
0
1
Analog Loopback
1
0
Remote Loopback
1
1
Digital Loopback
TABLE 12: MICROPROCESSOR REGISTER BIT DESCRIPTION
CHANNEL CONTROL REGISTER (0X06H, 0X0AH, 0X0EH, 0X12H, 0X16H, 0X1AH, 0X1EH, 0X22H)
BIT
NAME
D7
Reserved
D6
Reserved
Register
Type
Default
Value
(HW reset)
This Register Bit is Not Used
R/W
X
This Register Bit is Not Used
R/W
X
FUNCTION
38
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 12: MICROPROCESSOR REGISTER BIT DESCRIPTION
CHANNEL CONTROL REGISTER (0X06H, 0X0AH, 0X0EH, 0X12H, 0X16H, 0X1AH, 0X1EH, 0X22H)
Register
Type
Default
Value
(HW reset)
Alarm Indication Signal Interrupt Status
"0" = No Change
"1" = Change in Status Occured
RUR
0
DMOI_n
Driver Monitor Output Interrupt Status
"0" = No Change
"1" = Change in Status Occured
RUR
0
D3
RLOSI_n
Receiver Loss of Signal Interrupt Status
"0" = No Change
"1" = Change in Status Occured
RUR
0
D2
Reserved
This Register Bit is Not Used
R/W
X
D1
Reserved
This Register Bit is Not Used
R/W
X
D0
Reserved
This Register Bit is Not Used
R/W
X
BIT
NAME
D5
AISI_n
D4
FUNCTION
TABLE 13: MICROPROCESSOR REGISTER BIT DESCRIPTION
CHANNEL CONTROL REGISTER (0X07H, 0X0BH, 0X0FH, 0X13H, 0X17H, 0X1BH, 0X1FH, 0X23H)
BIT
NAME
D7
Reserved
D6
Reserved
D5
AISS_n
Register
Type
Default
Value
(HW reset)
This Register Bit is Not Used
R/W
X
This Register Bit is Not Used
R/W
X
Alarm Indication Signal Alarm Status
The alarm indication signal detection is always active regardless if
the interrupt generation is disabled. This bit indicates the AIS
activity. An interrupt will not occur unless the AISIE is set to "1" in
the channel register 0x04h and GIE is set to "1" in the global register 0xE0h.
RO
0
RO
0
FUNCTION
"0" = No Alarm
"1" = An all ones signal is detected
D4
DMOS_n
Driver Monitor Output Alarm Status
The Driver Monitor output is always active regardless if the interrupt generation is disabled. This bit indicates the DMO activity. An
interrupt will not occur unless the DMOIE is set to "1" in the channel register 0x04h and GIE is set to "1" in the global register
0xE0h.
"0" = No Alarm
"1" = Transmit output driver has failures
39
�XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
xr
REV. 1.0.0
CHANNEL CONTROL REGISTER (0X07H, 0X0BH, 0X0FH, 0X13H, 0X17H, 0X1BH, 0X1FH, 0X23H)
BIT
NAME
FUNCTION
D3
RLOSS_n
Receiver Loss of Signal Alarm Status
The receiver loss of signal detection is always active regardless if
the interrupt generation is disabled. This bit indicates the RLOS
activity. An interrupt will not occur unless the RLOSIE is set to "1"
in the channel register 0x04h and GIE is set to "1" in the global
register 0xE0h.
Register
Type
Default
Value
(HW reset)
RO
0
"0" = No Alarm
"1" = An RLOS condition is present
D2
Reserved
This Register Bit is Not Used
R/W
X
D1
Reserved
This Register Bit is Not Used
R/W
X
D0
Reserved
This Register Bit is Not Used
R/W
X
40
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
ELECTRICAL CHARACTERISTICS
TABLE 14: ABSOLUTE MAXIMUM RATINGS
Storage Temperature
-65°C to +150°C
Operating Temperature
-40°C to +85°C
Supply Voltage
-0.5V to +3.8V
Vin
-0.5V to +5.5V
TABLE 15: DC DIGITAL INPUT AND OUTPUT ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
VDD
3.13
3.3
3.46
V
Input High Voltage
VIH
2.0
-
5.0
V
Input Low Voltage
VIL
-0.5
-
0.8
V
Output High Voltage IOH=2.0mA
VOH
2.4
-
Output Low Voltage IOL=2.0mA
VOL
-
-
0.4
V
Input Leakage Current
IL
-
-
±10
µA
Input Capacitance
CI
-
5.0
Output Lead Capacitance
CL
-
-
Power Supply Voltage
V
pF
25
pF
NOTE: Input leakage current excludes pins that are internally pulled "Low" or "High".
TABLE 16: AC ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
MCLK Clock Duty Cycle
40
-
60
%
MCLK Clock Tolerance
-
±50
-
ppm
TABLE 17: POWER CONSUMPTION
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
TEST
CONDITION
MODE
IMPEDANCE
RECEIVER
TRANSMITTER
TYP
MAX
UNIT
E1
75Ω
1:1
1:2
1.0
1.30
1.1
1.4
W
50% ones
100% ones
E1
120Ω
1:1
1:2
0.9
1.2
1.0
1.3
W
50% ones
100% ones
E1
75Ω/120Ω
1.1
1.2
0.30
0.4
W
Transmitter
OFF
41
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 18: RECEIVER ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
MIN
TYP
MAX
UNIT
TEST CONDITION
-
32
-
15
24
-
dB
12.5
-
-
% ones
9
11
-
dB
-18
-14
-
13
-
kΩ
37
0.2
-
-
UIp-p
-
36
-
-0.5
kHz
dB
ITU-G.736
-
10
1.5
-
Hz
Hz
ITU-G.736
14
20
16
-
-
dB
dB
dB
ITU-G.703
Receiver Loss of Signal
Number of consecutive zeros
before RLOS is declared
Input signal level at RLOS
RLOS clear
Receiver Sensitivity (short haul
with cable loss)
Interference Margin
Input Impedance
Input Jitter Tolerance
1Hz
10kHz - 100kHz
Recovered Clock Jitter
Transfer Corner Frequency
Peaking Amplitude
Jitter Attenuator Corner Frequency
JABW = "0"
JABW = "1"
Return Loss
51kHz - 102kHz
102kHz - 2048kHz
2048kHz - 3072kHz
42
Cable attenuation @ 1024kHz
ITU-G.775, ETSI 300 233
With nominal pulse amplitude of
3.0V for 120Ω and 2.37V for
75Ω with 6dB cable loss.
ITU-G.823
UIp-p
�xr
XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 19: E1 TRANSMITTER ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
MIN
TYP
MAX
UNIT
AMI Output Pulse Amplitude
75Ω
120Ω
2.13
2.70
2.37
3.00
2.60
3.30
V
V
Output Pulse Width
224
244
264
ns
Output Pulse Width Ratio
0.95
-
1.05
ITU-G.703
Output Pulse Amplitude Ratio
0.95
-
1.05
ITU-G.703
-
0.025
0.05
UIp-p
8
8
8
-
-
dB
dB
dB
Jitter Added by the Transmitter
Output
Output Return Loss
51kHz - 102kHz
102kHz - 2048kHz
2048kHz - 3072kHz
43
TEST CONDITION
1:2 Transformer
Broad Band with jitter free TCLK
applied to the input.
ETSI 300 166
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
ORDERING INFORMATION
PRODUCT NUMBER
PACKAGE
OPERATING TEMPERATURE RANGE
XRT83SL28IV
144 LEAD TQFP
-400C to +850C
PACKAGE DIMENSIONS
144 LEAD THIN QUAD FLAT PACK
(20 x 20 x 1.4 mm TQFP)
rev. 1.00
D
D1
108
73
109
72
D1
D
37
144
1
36
A2
e
B
C
A
Seating Plane
α
A1
L
Note: The control dimension is the millimeter column
SYMBOL
INCHES
MIN
MAX
MILLIMETERS
MIN
MAX
A
A1
A2
B
C
D
D1
e
L
α
β
0.055
0.063
0.002
0.006
0.053
0.057
0.007
0.011
0.004
0.008
0.858
0.874
0.783
0.791
0.020 BSC
0.018
0.03
7o
0o
0.510
0.490
1.4
1.6
0.05
0.15
1.35
1.45
0.17
0.27
0.20
0.09
21.8
22.2
19.9
20.1
0.50 BSC
0.45
0.75
7o
0o
12.45
12.96
44
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XRT83SL28
8-CHANNEL E1 SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
REVISION HISTORY
REVISION #
DATE
DESCRIPTION
P1.0.0
06/02/03
First release of the 8-Channel LIU Preliminary Datasheet
P1.0.1
09/23/03
Updated the Receive Sensitivity in the Electrical Specification. Removed the
Copper Slug reference in the package drawing.
P1.0.2
08/4/04
Modified definitions of Reset (28) and HW/Host (81) pins.
P1.0.3
08/12/04
Edited descriptions in sections 1.2, 1.3,1.4, 1.5, 1.7, 2.4, 2.6 and 2.8
P1.0.4
08/30/04
Made edits to LBM[1:0] pin numbers were reversed, made minor word edits to
Clock Data recovery and RLOS sections. Made edits to LB1 and LB0 in table 11,
Analog and Remote were reversed
P1.0.5
01/28/05
Added Power Consumption Numbers
1.0.0
04/12/05
Added Max power Consumption. Removed Preliminary.
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 2005 EXAR Corporation
Datasheet April 2005.
Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited.
45
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