EXAR XRT83L314IB

XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
MAY 2004
REV. 1.0.0
GENERAL DESCRIPTION
Additional features include RLOS, a 16-bit LCV
counter for each channel, AIS, QRSS generation/
detection, Network Loop Code generation/detection,
TAOS, DMO, and diagnostic loopback modes.
The XRT83L314 is a fully integrated 14-channel longhaul and short-haul line interface unit (LIU) that
operates from a single 3.3V power supply. Using
internal termination, the LIU provides one bill of
materials to operate in T1, E1, or J1 mode
independently on a per channel basis with minimum
external components.
The LIU features are
programmed through a standard microprocessor
interface. 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.
APPLICATIONS
•
•
•
•
•
•
•
•
•
•
The on-chip clock synthesizer generates T1/E1/J1
clock rates from a selectable external clock frequency
and has five output clock references that can be used
for external timing (8kHz, 1.544Mhz, 2.048Mhz,
nxT1/J1, nxE1).
T1 Digital Cross Connects (DSX-1)
ISDN Primary Rate Interface
CSU/DSU E1/T1/J1 Interface
T1/E1/J1 LAN/WAN Routers
Public Switching Systems and PBX Interfaces
T1/E1/J1 Multiplexer and Channel Banks
Integrated Multi-Service Access Platforms (IMAPs)
Integrated Access Devices (IADs)
Inverse Multiplexing for ATM (IMA)
Wireless Base Stations
FIGURE 1. BLOCK DIAGRAM OF THE XRT83L314
1 of 14 Channels
NLCD
Generation
TCLK
TPOS
TNEG
HDB3/B8ZS
Encoder
Tx Jitter
Attenuator
Remote
Loopback
RCLK
RPOS
RNEG
HDB3/B8ZS
Decoder
Driver
Monitor
Tx Pulse
Shaper &
Pattern Gen
Timing
Control
Digital
Loopback
Rx Jitter
Attenuator
TRING
Analog
Loopback
QRSS
Generation
& Detection
Peak
Detector
& Slicer
Clock & Data
Recovery
TTIP
Line
Driver
Rx
Equalizer
RTIP
RRING
Rx Equalizer
Control
NLCD
Detection
AIS & LOS
Detector
DMO
RLOS
ICT
TEST
Test
Programmable Master
Clock Synthesizer
Microprocessor
Interface
8kHzOUT
MCLKE1out
MCLKT1out
MCLKE1Nout
MCLKT1Nout
RxON
TxON
MCLKin
CS[5:1]
[7:0]
DATA
Reset
[10:0]
ADDR
uPCLK
uPTS2
uPTS1
uPTS0
RD_WE
WR_R/W
CS
ALE
INT
RDY_TA
RxTSEL
Exar Corporation 48720 Kato Road, Fremont CA, 94538 • (510) 668-7000 • FAX (510) 668-7017 • www.exar.com
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
• Receive monitor mode handles 0 to 29dB resistive
FEATURES
attenuation (flat loss) along with 0 to 6dB cable loss
for both T1 and E1.
• Fully integrated 14-Channel short haul and long
haul transceivers for T1/J1 (1.544MHz) and E1
(2.048MHz) applications.
• Receiver line attenuation indication output in 1dB
steps.
• T1/E1/J1 short haul, long haul, and clock rate are
• Loss of signal (RLOS) according to ITU-T G.775/
per port selectable through software without
changing components.
ETS300233 (E1) and ANSI T1.403 (T1/J1).
• Internal Impedance matching on both receive and
• Programmable receive slicer threshold (45%, 50%,
transmit for 75Ω (E1), 100Ω (T1), 110Ω (J1), and
120Ω (E1) applications are per port selectable
through software without changing components.
55%, or 68%) for improved receiver interference
immunity.
• Programmable data stream muting upon RLOS
• Power down on a per channel basis with
detection.
independent receive and transmit selection.
• On-Chip HDB3/B8ZS encoder/decoder with an
• Five pre-programmed transmit pulse settings for T1
internal 16-bit LCV counter for each channel.
short haul applications.
• On-Chip digital clock recovery circuit for high input
• Arbitrary pulse generator for T1 and E1 modes.
• Transmit line build outs (LBO) for T1 long haul
jitter tolerance.
• QRSS pattern generator and detection for testing
applications from 0dB to -22.5dB in three -7.5dB
steps on a per channel basis.
and monitoring.
• Error and bipolar violation insertion and detection.
• Transmit all ones (TAOS) and in-band network loop
• On-Chip transmit short-circuit protection and
limiting protects line drivers from damage on a per
channel basis.
up and loop down code generation.
• Automatic loop code detection for remote loopback
• Independent Crystal-Less digital jitter attenuators
activation.
(JA) with 32-Bit or 64-Bit FIFO for the receive and
transmit paths
• Supports local analog, remote, digital, and dual
loopback modes.
• On-Chip frequency multiplier generates T1 or E1
• Low Power dissipation: 170mW per channel (50%
master clocks from a variety of external clock
sources (8, 16, 56, 64, 128, 256kHz and 1X, 2X,
4X, 8X T1 or E1)
density).
• 250mW per channel maximum power dissipation
• Driver failure monitor output (DMO) alerts of
(100% density).
possible system or external component problems.
• Single 3.3V supply operation (3V to 5V I/O
• Transmit outputs and receive inputs may be "High"
impedance
for
protection
or
applications on a per channel basis.
tolerant).
redundancy
• 304-Pin TBGA package
• -40°C to +85°C Temperature Range
• Supports gapped clocks for mapper/multiplexer
• Support for automatic protection switching.
• 1:1 and 1+1 protection without relays.
• Selectable receiver sensitivity from 0 to 36dB cable
applications.
loss in T1 @ 772kHz, and 0 to 43dB cable loss in
E1 @ 1,024kHz.
PRODUCT ORDERING INFORMATION
PRODUCT NUMBER
PACKAGE TYPE
OPERATING TEMPERATURE RANGE
XRT83L314IB
304 Lead TBGA
-40°C to +85°C
2
CSB
RESETB
A[8]
TRING_8
RVDD_8
RCLK_8
RCLK_9
TVDD_9
TRING_9
A[10]
unnamed.2
RGND_8
RRING_8
RTIP_8
RVDD_9
RTIP_9
RRING_9
RGND_9
TTIP_9
RNEG_9
RNEG_8
TTIP_8
TVDD_8
unnamed.7
DVDD_DRV
CSB1
CSB4
21
3
unnamed.4
TGND_9
RPOS_9
RPOS_8
TGND_8
A[9]
DVDD_PRE
CSB3
CSB5
unnamed.5
UPTS1
A[0]
RVDD_12
DGND_DRV
UPTS2
A[4]
A[3]
UPTS0
RNEG_12
TXOFF
A[5]
A[2]
DVDD_PRE
RPOS_12
TGND_12
RCLK_12
TTIP_12
TVDD_12
RTIP_12
TRING_11
RGND_12
TVDD_11
TGND_11
RRING_12
RVDD_11
RTIP_11
TTIP_11
RPOS_11
TRING_12
RCLK_11
RVDD_10
RNEG_11
RPOS_10
RGND_11
RCLK_10
RTIP_10
RNEG_10
TGND_10
DVDD_DRV DVDD_11_12 DGND_11_12
TVDD_10
RRING_10
TTIP_10
RRING_11
TRING_10
RGND_10
19
18
17
16
15
13
RTIP_7 RRING_7
14
RCLK_6
RVDD_0
RTIP_0
TNEG_12 TCLK_11 TNEG_13 VDDPLL_11 RVDD_13 RTIP_13 RRING_13 RGND_13 RGND_0 RRING_0
RXTSEL RPOS_13 TGND_13 DGND_13_0 TGND_0 RPOS_0 GNDPLL_12
RXOFF TPOS_11 TPOS_13 VDDPLL_12 DGND_UP RCLK_13 TVDD_13 TRING_13 TRING_0 TVDD_0
TCLK_12 TCLK_13
Bottom View
7
6
5
4
MCLKT1xN
GNDPLL_11
DGND_PRE
DGND_DRV
TPOS_0
TCLK_0
TNEG_0
TNEG_2
TNEG_1
TCLK_6
TNEG_6
TPOS_6
TCLK_2
TPOS_2
TPOS_1
D[3]
TPOS_3
TNEG_3
TCLK_3
TVDD_4
TTIP_4
RNEG_4
RNEG_5
TTIP_5
unnamed.13
DVDD_PRE
INTB
TCLK_5
3
unnamed.12
1
RRING_4
RTIP_4
RVDD_4
RTIP_5
RRING_5
RGND_5
unnamed.14 unnamed.16
DVDD_3_4_5 RGND_4
TRING_4
RCLK_4
RCLK_5
RVDD_5
TVDD_5
TRING_5
DGND_DRV unnamed.17
ICTB
2
DMO
D[7]
D[2]
D[1]
D[4]
D[0]
TCLK_1
RPOS_1
TGND_1
TVDD_1
DGND_1_2
TGND_2
RPOS_2
RPOS_3
TGND_3
D[5]
D[6]
RDY_DTACKB
RNEG_1
TTIP_1
TRING_1
DGND_DRV
TVDD_2
TTIP_2
RNEG_2
RNEG_3
TTIP_3
RLOS
unnamed.9
RTIP_1
RRING_1
RGND_2
RRING_2
RTIP_2
RVDD_3
RTIP_3
RRING_3
RGND_3
DVDD_DRV unnamed.0
UPCLK
RCLK_1
RVDD_1
RGND_1
DVDD_1_2
TRING_2
RVDD_2
RCLK_2
RCLK_3
TVDD_3
TRING_3
DGND_PRE AGND_BIAS DGND_3_4_5 unnamed.10
AVDD_BIAS DVDD_DRV
TGND_4
RPOS_4
RPOS_5
TGND_5
unnamed.11
TEST
TPOS_5
TPOS_4
DVDD_PRE
TNEG_5
TNEG_4
TCLK_4
RVDD_6 MCLKOUT_T1 MCLKIN MCLKOUT_E1 MCLKE1xN
8
DGND_6_7 TTIP_6 RNEG_6 GNDPLL_22 GNDPLL_21
TRING_7 TRING_6 TVDD_6
RTIP_6
9
TCLK_10 DGND_PRE RPOS_7 TGND_7 DVDD_6_7 TGND_6 RPOS_6 DVDD_DRV EIGHT_KHZ
TTIP_7
10
RCLK_0
A[7]
RDB_DSB TPOS_9
TNEG_7 VDDPLL_22 RNEG_7
11
RGND_7 RGND_6 RRING_6
12
TPOS_12 TNEG_11 DVDD_DRV DVDD_UP RNEG_13 TTIP_13 DVDD_13_0 TTIP_0 RNEG_0
A[6]
A[1]
CSB2
ALE_AS TNEG_8 TCLK_9
TPOS_8 TNEG_9 TNEG_10 TCLK_7 VDDPLL_21 RCLK_7 TVDD_7
WRB_RWB TCLK_8 TPOS_10 TPOS_7 DGND_DRV RVDD_7
20
DGND_8_9_10 unnamed.6 DGND_DRV DGND_PRE
DVDD_8_9_10 unnamed.1 unnamed.3
22
23
AC
AB
AA
Y
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
PIN OUT OF THE XRT83L314
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE OF CONTENTS
GENERAL DESCRIPTION.............................................................................................................. 1
APPLICATIONS .......................................................................................................................................................... 1
FIGURE 1. BLOCK DIAGRAM OF THE XRT83L314 .................................................................................................................................... 1
FEATURES ..................................................................................................................................................................... 2
PRODUCT ORDERING INFORMATION ..................................................................................................2
PIN OUT OF THE XRT83L314........................................................................................................ 3
TABLE OF CONTENTS ............................................................................................................I
PIN DESCRIPTIONS....................................................................................................................... 3
MICROPROCESSOR ........................................................................................................................................................ 3
RECEIVER SECTION ....................................................................................................................................................... 4
TRANSMITTER SECTION.................................................................................................................................................. 7
CONTROL FUNCTION ...................................................................................................................................................... 9
CLOCK SECTION ............................................................................................................................................................ 9
POWER AND GROUND .................................................................................................................................................. 10
NO CONNECTS ............................................................................................................................................................ 12
1.0 CLOCK SYNTHESIZER .......................................................................................................................13
TABLE 1: INPUT CLOCK SOURCE SELECT .............................................................................................................................................. 13
FIGURE 2. SIMPLIFIED BLOCK DIAGRAM OF THE CLOCK SYNTHESIZER................................................................................................... 14
1.1 ALL T1/E1 MODE ........................................................................................................................................... 14
2.0 RECEIVE PATH LINE INTERFACE .....................................................................................................14
FIGURE 3. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE PATH ............................................................................................................ 14
2.1 LINE TERMINATION (RTIP/RRING) .............................................................................................................. 15
2.1.1 CASE 1: INTERNAL TERMINATION.......................................................................................................................... 15
FIGURE 4. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION .......................................................................................... 15
TABLE 2: SELECTING THE INTERNAL IMPEDANCE.................................................................................................................................... 15
2.1.2 CASE 2: INTERNAL TERMINATION WITH ONE EXTERNAL FIXED RESISTOR FOR ALL MODES..................... 16
FIGURE 5. TYPICAL CONNECTION DIAGRAM USING ONE EXTERNAL FIXED RESISTOR.............................................................................. 16
TABLE 3: SELECTING THE VALUE OF THE EXTERNAL FIXED RESISTOR .................................................................................................... 16
2.2 EQUALIZER CONTROL ................................................................................................................................. 17
FIGURE 6. SIMPLIFIED BLOCK DIAGRAM OF THE EQUALIZER AND PEAK DETECTOR ................................................................................. 17
2.3 CABLE LOSS INDICATOR ............................................................................................................................. 17
FIGURE 7. SIMPLIFIED BLOCK DIAGRAM OF THE CABLE LOSS INDICATOR................................................................................................ 17
2.4 EQUALIZER ATTENUATION FLAG .............................................................................................................. 18
FIGURE 8. SIMPLIFIED BLOCK DIAGRAM OF THE EQUALIZER ATTENUATION FLAG .................................................................................... 18
2.5 PEAK DETECTOR AND SLICER ................................................................................................................... 18
TABLE 4: SELECTING THE SLICER LEVEL FOR THE PEAK DETECTOR ....................................................................................................... 18
2.6 CLOCK AND DATA RECOVERY ................................................................................................................... 19
FIGURE 9. RECEIVE DATA UPDATED ON THE RISING EDGE OF RCLK..................................................................................................... 19
FIGURE 10. RECEIVE DATA UPDATED ON THE FALLING EDGE OF RCLK................................................................................................. 19
2.6.1 RECEIVE SENSITIVITY .............................................................................................................................................. 20
FIGURE 11. TEST CONFIGURATION FOR MEASURING RECEIVE SENSITIVITY ............................................................................................ 20
TABLE 5: TIMING SPECIFICATIONS FOR RCLK/RPOS/RNEG................................................................................................................. 20
2.6.2 INTERFERENCE MARGIN ......................................................................................................................................... 21
FIGURE 12. TEST CONFIGURATION FOR MEASURING INTERFERENCE MARGIN ......................................................................................... 21
2.6.3 GENERAL ALARM DETECTION AND INTERRUPT GENERATION ........................................................................ 21
FIGURE 13. INTERRUPT GENERATION PROCESS BLOCK ......................................................................................................................... 21
2.6.3.1 RLOS (RECEIVER LOSS OF SIGNAL) ..................................................................................................................... 21
FIGURE 14. ANALOG RECEIVE LOS OF SIGNAL FOR T1/E1/J1................................................................................................................ 22
2.6.3.2 EXLOS (EXTENDED LOSS OF SIGNAL) .................................................................................................................. 22
2.6.3.3 AIS (ALARM INDICATION SIGNAL) ......................................................................................................................... 22
2.6.3.4 NLCD (NETWORK LOOP CODE DETECTION) .......................................................................................................... 22
TABLE 6: ANALOG RLOS DECLARE/CLEAR (TYPICAL VALUES) FOR T1/E1 ............................................................................................. 22
FIGURE 15. PROCESS BLOCK FOR AUTOMATIC LOOP CODE DETECTION ................................................................................................ 23
2.6.3.5 FLSD (FIFO LIMIT STATUS DETECTION) ............................................................................................................... 24
2.6.3.6 LCV/OFD (LINE CODE VIOLATION / COUNTER OVERFLOW DETECTION) ................................................................. 24
2.7 RECEIVE JITTER ATTENUATOR .................................................................................................................. 24
2.8 HDB3/B8ZS DECODER .................................................................................................................................. 24
2.9 RPOS/RNEG/RCLK ........................................................................................................................................ 25
FIGURE 16. SINGLE RAIL MODE WITH A FIXED REPEATING "0011" PATTERN ......................................................................................... 25
I
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
FIGURE 17. DUAL RAIL MODE WITH A FIXED REPEATING "0011" PATTERN ............................................................................................ 25
2.10 RXMUTE (RECEIVER LOS WITH DATA MUTING) ..................................................................................... 25
FIGURE 18. SIMPLIFIED BLOCK DIAGRAM OF THE RXMUTE FUNCTION................................................................................................... 25
3.0 TRANSMIT PATH LINE INTERFACE ................................................................................................. 26
FIGURE 19. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT PATH ......................................................................................................... 26
3.1 TCLK/TPOS/TNEG DIGITAL INPUTS ............................................................................................................ 26
FIGURE 20. TRANSMIT DATA SAMPLED ON FALLING EDGE OF TCLK...................................................................................................... 26
FIGURE 21. TRANSMIT DATA SAMPLED ON RISING EDGE OF TCLK........................................................................................................ 26
3.2 HDB3/B8ZS ENCODER .................................................................................................................................. 27
TABLE 7: TIMING SPECIFICATIONS FOR TCLK/TPOS/TNEG.................................................................................................................. 27
TABLE 8: EXAMPLES OF HDB3 ENCODING ............................................................................................................................................ 27
TABLE 9: EXAMPLES OF B8ZS ENCODING ............................................................................................................................................. 27
3.3 TRANSMIT JITTER ATTENUATOR ............................................................................................................... 28
3.4 TAOS (TRANSMIT ALL ONES) ..................................................................................................................... 28
FIGURE 22. TAOS (TRANSMIT ALL ONES) ............................................................................................................................................ 28
3.5 TRANSMIT DIAGNOSTIC FEATURES .......................................................................................................... 28
TABLE 10: MAXIMUM GAP WIDTH FOR MULTIPLEXER/MAPPER APPLICATIONS......................................................................................... 28
3.5.1 ATAOS (AUTOMATIC TRANSMIT ALL ONES)......................................................................................................... 29
FIGURE 23. SIMPLIFIED BLOCK DIAGRAM OF THE ATAOS FUNCTION ..................................................................................................... 29
3.5.2 NETWORK LOOP UP CODE...................................................................................................................................... 29
FIGURE 24. NETWORK LOOP UP CODE GENERATION ............................................................................................................................ 29
3.5.3 NETWORK LOOP DOWN CODE ............................................................................................................................... 29
FIGURE 25. NETWORK LOOP DOWN CODE GENERATION ....................................................................................................................... 29
3.5.4 QRSS GENERATION.................................................................................................................................................. 30
3.6 TRANSMIT PULSE SHAPER AND FILTER ................................................................................................... 30
3.6.1 T1 LONG HAUL LINE BUILD OUT (LBO).................................................................................................................. 30
FIGURE 26. LONG HAUL LINE BUILD OUT WITH -7.5DB ATTENUATION .................................................................................................... 30
TABLE 11: RANDOM BIT SEQUENCE POLYNOMIALS ................................................................................................................................ 30
FIGURE 27. LONG HAUL LINE BUILD OUT WITH -15DB ATTENUATION ..................................................................................................... 31
FIGURE 28. LONG HAUL LINE BUILD OUT WITH -22.5DB ATTENUATION .................................................................................................. 31
3.6.2 T1 SHORT HAUL LINE BUILD OUT (LBO) ............................................................................................................... 32
3.6.3 ARBITRARY PULSE GENERATOR FOR T1 AND E1............................................................................................... 32
FIGURE 29. ARBITRARY PULSE SEGMENT ASSIGNMENT ......................................................................................................................... 32
3.7 DMO (DIGITAL MONITOR OUTPUT) ............................................................................................................. 32
TABLE 12: SHORT HAUL LINE BUILD OUT.............................................................................................................................................. 32
3.8 LINE TERMINATION (TTIP/TRING) ............................................................................................................... 33
FIGURE 30. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION ......................................................................................... 33
4.0 T1/E1 APPLICATIONS ........................................................................................................................ 34
4.1 LOOPBACK DIAGNOSTICS .......................................................................................................................... 34
4.1.1 LOCAL ANALOG LOOPBACK .................................................................................................................................. 34
FIGURE 31. SIMPLIFIED BLOCK DIAGRAM OF LOCAL ANALOG LOOPBACK ................................................................................................ 34
4.1.2 REMOTE LOOPBACK ................................................................................................................................................ 34
FIGURE 32. SIMPLIFIED BLOCK DIAGRAM OF REMOTE LOOPBACK .......................................................................................................... 34
4.1.3 DIGITAL LOOPBACK ................................................................................................................................................. 35
FIGURE 33. SIMPLIFIED BLOCK DIAGRAM OF DIGITAL LOOPBACK ........................................................................................................... 35
4.1.4 DUAL LOOPBACK ..................................................................................................................................................... 35
FIGURE 34. SIMPLIFIED BLOCK DIAGRAM OF DUAL LOOPBACK ............................................................................................................... 35
4.2 84-CHANNEL T1/E1 MULTIPLEXER/MAPPER APPLICATIONS ................................................................. 36
FIGURE 35. SIMPLIFIED BLOCK DIAGRAM OF AN 84-CHANNEL APPLICATION ........................................................................................... 36
TABLE 13: CHIP SELECT ASSIGNMENTS ................................................................................................................................................ 36
4.3 LINE CARD REDUNDANCY .......................................................................................................................... 37
4.3.1 1:1 AND 1+1 REDUNDANCY WITHOUT RELAYS .................................................................................................... 37
4.3.2 TRANSMIT INTERFACE WITH 1:1 AND 1+1 REDUNDANCY .................................................................................. 37
FIGURE 36. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR 1:1 AND 1+1 REDUNDANCY ................................................ 37
4.3.3 RECEIVE INTERFACE WITH 1:1 AND 1+1 REDUNDANCY..................................................................................... 37
FIGURE 37. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR 1:1 AND 1+1 REDUNDANCY .................................................. 38
4.3.4 N+1 REDUNDANCY USING EXTERNAL RELAYS ................................................................................................... 38
4.3.5 TRANSMIT INTERFACE WITH N+1 REDUNDANCY ................................................................................................ 39
FIGURE 38. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR N+1 REDUNDANCY ............................................................ 39
4.3.6 RECEIVE INTERFACE WITH N+1 REDUNDANCY ................................................................................................... 40
FIGURE 39. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR N+1 REDUNDANCY .............................................................. 40
4.4 POWER FAILURE PROTECTION .................................................................................................................. 41
4.5 OVERVOLTAGE AND OVERCURRENT PROTECTION ............................................................................... 41
4.6 NON-INTRUSIVE MONITORING .................................................................................................................... 41
II
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
FIGURE 40. SIMPLIFIED BLOCK DIAGRAM OF A NON-INTRUSIVE MONITORING APPLICATION ..................................................................... 41
5.0 MICROPROCESSOR INTERFACE BLOCK ........................................................................................42
TABLE 14: SELECTING THE MICROPROCESSOR INTERFACE MODE .......................................................................................................... 42
FIGURE 41. SIMPLIFIED BLOCK DIAGRAM OF THE MICROPROCESSOR INTERFACE BLOCK ........................................................................ 42
5.1 THE MICROPROCESSOR INTERFACE BLOCK SIGNALS ......................................................................... 43
TABLE 15: XRT84L314 MICROPROCESSOR INTERFACE SIGNALS THAT EXHIBIT CONSTANT ROLES IN BOTH INTEL AND MOTOROLA MODES 43
TABLE 16: INTEL MODE: MICROPROCESSOR INTERFACE SIGNALS ........................................................................................................... 43
TABLE 17: MOTOROLA MODE: MICROPROCESSOR INTERFACE SIGNALS ................................................................................................. 44
5.2 INTEL MODE PROGRAMMED I/O ACCESS (ASYNCHRONOUS) ............................................................... 45
FIGURE 42. INTEL µP INTERFACE SIGNALS DURING PROGRAMMED I/O READ AND WRITE OPERATIONS .................................................. 46
TABLE 18: INTEL MICROPROCESSOR INTERFACE TIMING SPECIFICATIONS .............................................................................................. 46
5.3 MOTOROLA MODE PROGRAMMED I/O ACCESS (SYNCHRONOUS) ....................................................... 47
FIGURE 43. MOTOROLA µP INTERFACE SIGNALS DURING PROGRAMMED I/O READ AND WRITE OPERATIONS .......................................... 48
TABLE 19: INTEL MICROPROCESSOR INTERFACE TIMING SPECIFICATIONS .............................................................................................. 48
FIGURE 44. MOTOROLA 68K µP INTERFACE SIGNALS DURING PROGRAMMED I/O READ AND WRITE OPERATIONS .................................. 49
TABLE 20: MOTOROLA 68K MICROPROCESSOR INTERFACE TIMING SPECIFICATIONS .............................................................................. 49
TABLE 21: MICROPROCESSOR REGISTER ADDRESS (ADDR[7:0]) .......................................................................................................... 50
TABLE 22: MICROPROCESSOR REGISTER CHANNEL DESCRIPTION.......................................................................................................... 50
TABLE 23: MICROPROCESSOR REGISTER GLOBAL DESCRIPTION ............................................................................................................ 51
TABLE 24: MICROPROCESSOR REGISTER 0X00H BIT DESCRIPTION ........................................................................................................ 52
TABLE 25: EQUALIZER CONTROL AND TRANSMIT LINE BUILD OUT .......................................................................................................... 52
TABLE 26: MICROPROCESSOR REGISTER 0X01H BIT DESCRIPTION ........................................................................................................ 54
TABLE 27: MICROPROCESSOR REGISTER 0X02H BIT DESCRIPTION ........................................................................................................ 55
TABLE 28: MICROPROCESSOR REGISTER 0X03H BIT DESCRIPTION ........................................................................................................ 56
TABLE 29: MICROPROCESSOR REGISTER 0X04H BIT DESCRIPTION ........................................................................................................ 57
TABLE 30: MICROPROCESSOR REGISTER 0X05H BIT DESCRIPTION ........................................................................................................ 58
TABLE 31: MICROPROCESSOR REGISTER 0X06H BIT DESCRIPTION ........................................................................................................ 59
TABLE 32: MICROPROCESSOR REGISTER 0X07H BIT DESCRIPTION ........................................................................................................ 60
TABLE 33: MICROPROCESSOR REGISTER 0X08H BIT DESCRIPTION ........................................................................................................ 61
TABLE 34: MICROPROCESSOR REGISTER 0X09H BIT DESCRIPTION ........................................................................................................ 61
TABLE 35: MICROPROCESSOR REGISTER 0X0AH BIT DESCRIPTION ....................................................................................................... 61
TABLE 36: MICROPROCESSOR REGISTER 0X0BH BIT DESCRIPTION ....................................................................................................... 62
TABLE 37: MICROPROCESSOR REGISTER 0X0CH BIT DESCRIPTION ....................................................................................................... 62
TABLE 38: MICROPROCESSOR REGISTER 0X0DH BIT DESCRIPTION ....................................................................................................... 62
TABLE 39: MICROPROCESSOR REGISTER 0X0EH BIT DESCRIPTION ....................................................................................................... 62
TABLE 40: MICROPROCESSOR REGISTER 0X0FH BIT DESCRIPTION ........................................................................................................ 63
TABLE 41: MICROPROCESSOR REGISTER 0XE0H BIT DESCRIPTION ....................................................................................................... 63
TABLE 42: MICROPROCESSOR REGISTER 0XE1H BIT DESCRIPTION ....................................................................................................... 64
TABLE 43: MICROPROCESSOR REGISTER 0XE2H BIT DESCRIPTION ....................................................................................................... 65
TABLE 44: MICROPROCESSOR REGISTER 0XE3H BIT DESCRIPTION ....................................................................................................... 65
TABLE 45: MICROPROCESSOR REGISTER 0XE4H BIT DESCRIPTION ....................................................................................................... 66
TABLE 46: MICROPROCESSOR REGISTER 0XE5H BIT DESCRIPTION ....................................................................................................... 67
TABLE 47: MICROPROCESSOR REGISTER 0XE6H BIT DESCRIPTION ....................................................................................................... 68
TABLE 48: MICROPROCESSOR REGISTER 0XE7H BIT DESCRIPTION ....................................................................................................... 69
TABLE 49: MICROPROCESSOR REGISTER 0XE8H BIT DESCRIPTION ....................................................................................................... 69
CLOCK SELECT REGISTER ....................................................................................................... 70
FIGURE 45. REGISTER 0XE9H SUB REGISTERS ..................................................................................................................................... 70
TABLE 50: MICROPROCESSOR REGISTER 0XE9H BIT DESCRIPTION ....................................................................................................... 70
TABLE 51: MICROPROCESSOR REGISTER 0XEAH BIT DESCRIPTION ....................................................................................................... 72
TABLE 52: MICROPROCESSOR REGISTER 0XEBH BIT DESCRIPTION ....................................................................................................... 72
TABLE 53: E1 ARBITRARY SELECT ........................................................................................................................................................ 73
TABLE 54: MICROPROCESSOR REGISTER 0XFEH BIT DESCRIPTION ....................................................................................................... 74
TABLE 55: MICROPROCESSOR REGISTER 0XFFH BIT DESCRIPTION ....................................................................................................... 74
TABLE 56: ABSOLUTE MAXIMUM RATINGS ............................................................................................................................................. 75
TABLE 57: DC DIGITAL INPUT AND OUTPUT ELECTRICAL CHARACTERISTICS ........................................................................................... 75
TABLE 58: AC ELECTRICAL CHARACTERISTICS ...................................................................................................................................... 75
TABLE 59: POWER CONSUMPTION ........................................................................................................................................................ 76
TABLE 60: E1 RECEIVER ELECTRICAL CHARACTERISTICS ...................................................................................................................... 76
TABLE 61: T1 RECEIVER ELECTRICAL CHARACTERISTICS ...................................................................................................................... 77
TABLE 62: E1 TRANSMITTER ELECTRICAL CHARACTERISTICS................................................................................................................. 78
TABLE 63: T1 TRANSMITTER ELECTRICAL CHARACTERISTICS ................................................................................................................. 78
ORDERING INFORMATION ......................................................................................................... 79
PACKAGE DIMENSIONS (DIE DOWN) ....................................................................................... 79
REVISION HISTORY ...................................................................................................................................................... 80
III
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
PIN DESCRIPTIONS
MICROPROCESSOR
NAME
PIN
TYPE
DESCRIPTION
CS
A22
I
Chip Select Input
Active low signal. This signal enables the microprocessor interface by pulling
chip select "Low". The microprocessor interface is disabled when the chip
select signal returns "High".
ALE_TS
C19
I
Address Latch Enable Input (Transfer Start)
See the Microprocessor section of this datasheet for a description.
WR_R/W
A20
I
Write Strobe Input (Read/Write)
See the Microprocessor section of this datasheet for a description.
RD_WE
D18
I
Read Strobe Input (Write Enable)
See the Microprocessor section of this datasheet for a description.
RDY_TA
AA3
O
Ready Output (Transfer Acknowledge)
See the Microprocessor section of this datasheet for a description.
INT
B3
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.
µPCLK
AB2
I
Micro Processor Clock Input
In a synchronous microprocessor interface, µPCLK is used as the internal timing reference for programming the LIU.
ADDR10
ADDR9
ADDR8
ADDR7
ADDR6
ADDR5
ADDR4
ADDR3
ADDR2
ADDR1
ADDR0
A23
E20
C22
Y18
AA19
AB20
AC21
AB21
AA20
Y19
AC22
I
Address Bus Input
ADDR[10:8] is used as a chip select decoder. The LIU has 5 chip select output
pins for enabling up to 5 additional devices for accessing internal registers.
The LIU has the option to select itself (master device), up to 5 additional
devices, or all 6 devices simultaneously by setting the ADDR[10:8] pins specified below. ADDR[7:0] is a direct address bus for permitting access to the
internal registers.
ADDR[10:8]
000 = Master Device
001 = Chip Select Output 1 (Pin B21)
010 = Chip Select Output 2 (Pin D19)
011 = Chip Select Output 3 (Pin C20)
100 = Chip Select Output 4 (Pin A21)
101 = Chip Select Output 5 (Pin B20)
110 = Reserved
111 = All Chip Selects Active Including the Master Device
3
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
MICROPROCESSOR
NAME
PIN
TYPE
DESCRIPTION
DATA7
DATA6
DATA5
DATA4
DATA3
DATA2
DATA1
DATA0
AA4
AB3
AC3
AA5
Y6
AB4
AC4
AB5
I/O
µPTS2
µPTS1
µPTS0
AC23
AB22
AA21
I
Microprocessor Type Select Input
µPTS[2:0] are used to select the microprocessor type interface.
000 = Intel 68HC11, 8051, 80C188 (Asynchronous)
001 = Motorola 68K (Asynchronous)
111 = Motorola MPC8260, MPC860 Power PC (Synchronous)
Reset
B22
I
Hardware Reset Input
Active low signal. When this pin is pulled "Low" for more than 10µS, the internal registers are set to their default state. See the register description for the
default values.
Bi-directional Data Bus
DATA[7:0] is a bi-directional data bus used for read and write operations.
NOTE: Internally pulled "High" with a 50KΩ resistor.
CS5
CS4
CS3
CS2
CS1
B20
A21
C20
D19
B21
O
Chip Select Output
The XRT83L314 can be used to provide the necessary chip selects for up to 5
additional devices by using the 3 MSBs ADDR[10:8] from the 11-Bit address
bus. The LIU allows up to 84-channel applications with only using one chip
select. See the ADDR[10:0] definition in the pin description.
RECEIVER SECTION
NAME
PIN
TYPE
DESCRIPTION
RxON
AB19
I
Receive On/Off Input
Upon power up, the receivers are powered off. Turning the receivers On or Off
can be selected through the microprocessor interface by programming the
appropriate channel register if the hardware pin is pulled "High". If the hardware pin is pulled "Low", all channels are automatically turned off.
NOTE: Internally pulled "Low" with a 50KΩ resistor.
RxTSEL
Y15
I
Receive Termination Control
Upon power up, the receivers are in "High" impedance. Switching to internal
termination can be selected through the microprocessor interface by programming the appropriate channel register. However, to switch control to the hardware pin, RxTCNTL must be programmed to "1" in the appropriate global
register. Once control has been granted to the hardware pin, it must be pulled
"High" to switch to internal termination.
NOTE: Internally pulled "Low" with a 50kΩ resistor.
4
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
RECEIVER SECTION
NAME
PIN
TYPE
DESCRIPTION
RLOS
AB1
O
Receive Loss of Signal (Global Pin for All 14-Channels)
When a receive loss of signal occurs for any one of the 14-channels according
to ITU-T G.775, 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.
NOTE: This pin is for redundancy applications to initiate an automatic switch to
the backup card. For individual channel RLOS, see the register map.
RCLK13
RCLK12
RCLK11
RCLK10
RCLK9
RCLK8
RCLK7
RCLK6
RCLK5
RCLK4
RCLK3
RCLK2
RCLK1
RCLK0
AB14
Y22
R22
P22
G22
F22
B14
B9
F2
G2
P2
R2
AA2
AA9
O
RPOS13
RPOS12
RPOS11
RPOS10
RPOS9
RPOS8
RPOS7
RPOS6
RPOS5
RPOS4
RPOS3
RPOS2
RPOS1
RPOS0
Y14
W20
P20
N20
H20
G20
D14
D10
G4
H4
N4
P4
W4
Y10
O
Receive Clock Output
RCLK is the recovered clock from the incoming data stream. If the incoming
signal is absent or RxON is pulled "Low", 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 RCLKE in the appropriate global register.
NOTE: RCLKE is a global setting that applies to all 14 channels.
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.
5
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
RECEIVER SECTION
NAME
PIN
TYPE
DESCRIPTION
RNEG13
RNEG12
RNEG11
RNEG10
RNEG9
RNEG8
RNEG7
RNEG6
RNEG5
RNEG4
RNEG3
RNEG2
RNEG1
RNEG0
AA14
Y21
P21
N21
H21
G21
C14
C10
F3
G3
N3
P3
Y3
AA10
O
RNEG/LCV_OF Output
In dual rail mode, this pin is the receive negative data output. In single rail
mode, this pin is a Line Code Violation / Counter Overflow indicator. If LCV is
selected by programming the appropriate global register and If a line code violation, bi-polar violation, or excessive zeros occur, the LCV pin will pull "High"
for a minimum of one RCLK cycle. LCV will remain "High" until there are no
more violations. However, if OF is selected the LCV pin will pull "High" if the
internal LCV counter is saturated. The LCV pin will remain "High" until the LCV
counter is reset.
RTIP13
RTIP12
RTIP11
RTIP10
RTIP9
RTIP8
RTIP7
RTIP6
RTIP5
RTIP4
RTIP3
RTIP2
RTIP1
RTIP0
AC14
Y23
T23
P23
G23
E23
A14
A9
E1
G1
P1
T1
Y1
AC9
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.
RRING13
RRING12
RRING11
RRING10
RRING9
RRING8
RRING7
RRING6
RRING5
RRING4
RRING3
RRING2
RRING1
RRING0
AC13
W23
U23
N23
H23
D23
A13
A10
D1
H1
N1
U1
W1
AC10
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.
6
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TRANSMITTER SECTION
NAME
PIN
TYPE
DESCRIPTION
TxON
AC20
I
Transmit On/Off Input
Upon power up, the transmitters are powered off. Turning the transmitters On
or Off is selected through the microprocessor interface by programming the
appropriate channel register if this pin is pulled "High". If the TxON pin is
pulled "Low", all 14 transmitters are powered off.
NOTE:
DMO
Y4
O
TxON is ideal for redundancy applications. See the Redundancy
Applications Section of this datasheet for more details. Internally
pulled "Low" with a 50KΩ resistor.
Digital Monitor Output (Global Pin for All 14-Channels)
When no transmit output pulse is detected for more than 128 TCLK cycles on
one of the 14-channels, the DMO pin will go "High" for a minimum of one TCLK
cycle. DMO will remain "High" until the transmitter sends a valid pulse.
NOTE: This pin is for redundancy applications to initiate an automatic switch to
the backup card. For individual channel DMO, see the register map.
TCLK13
TCLK12
TCLK11
TCLK10
TCLK9
TCLK8
TCLK7
TCLK6
TCLK5
TCLK4
TCLK3
TCLK2
TCLK1
TCLK0
Y16
Y17
AC18
D16
C17
A19
B16
D7
A3
B5
B6
AC6
AC5
AC7
I
TPOS13
TPOS12
TPOS11
TPOS10
TPOS9
TPOS8
TPOS7
TPOS6
TPOS5
TPOS4
TPOS3
TPOS2
TPOS1
TPOS0
AB17
AA18
AB18
A18
D17
B19
A17
B7
C4
B4
D6
AB6
AA6
Y8
I
Transmit Clock Input
TCLK is the input facility clock used to sample the incoming TPOS/TNEG data.
If TCLK is absent, pulled "Low", or pulled "High", the transmitter outputs at
TTIP/TRING can be selected to send an all ones or an all zero signal by programming TCLKCNL in the appropriate global register. TPOS/TNEG data can
be sampled on either edge of TCLK selected by TCLKE in the appropriate global register.
NOTE: TCLKE is a global setting that applies to all 14 channels.
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.
NOTE: Internally pulled "Low" with a 50KΩ resistor.
7
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TRANSMITTER SECTION
NAME
PIN
TYPE
DESCRIPTION
TNEG13
TNEG12
TNEG11
TNEG10
TNEG9
TNEG8
TNEG7
TNEG6
TNEG5
TNEG4
TNEG3
TNEG2
TNEG1
TNEG0
AC17
AC19
AA17
B17
B18
C18
C16
C7
D5
C5
C6
AA7
Y7
AB7
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 left unconnected.
TTIP13
TTIP12
TTIP11
TTIP10
TTIP9
TTIP8
TTIP7
TTIP6
TTIP5
TTIP4
TTIP3
TTIP2
TTIP1
TTIP0
AA13
W21
R21
M21
J21
F21
C13
C11
E3
H3
M3
R3
W3
AA11
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.
TRING13
TRING12
TRING11
TRING10
TRING9
TRING8
TRING7
TRING6
TRING5
TRING4
TRING3
TRING2
TRING1
TRING0
AB12
V22
T20
M22
J22
D22
B12
B11
C2
H2
M2
U2
V3
AB11
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.
NOTE: Internally pulled "Low" with a 50KΩ resistor.
8
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
CONTROL FUNCTION
NAME
PIN
TYPE
TEST
D4
I
DESCRIPTION
Factory Test Mode
For normal operation, the TEST pin should be tied to ground.
NOTE: Internally pulled "Low" with a 50kΩ resistor.
ICT
A2
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.
CLOCK SECTION
NAME
PIN
TYPE
DESCRIPTION
MCLKin
A6
I
Master Clock Input
The master clock input can accept a wide range of inputs that can be used to
generate T1 or E1 clock rates on a per channel basis. See the register map for
details.
8kHzOUT
D8
O
8kHz Output Clock
MCLKE1out
A5
O
2.048MHz Output Clock
MCLKE1Nout
A4
O
2.048MHz, 4.096MHz, 8.192MHz, or 16.384MHz Output Clock
See the register map for programming details.
MCLKT1out
A7
O
1.544MHz Output Clock
MCLKT1Nout
B8
O
1.544MHz, 3.088MHz, 6.176MHz, or 12.352MHz Output Clock
See the register map for programming details.
9
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
POWER AND GROUND
NAME
PIN
TYPE
DESCRIPTION
TVDD13
TVDD12
TVDD11
TVDD10
TVDD9
TVDD8
TVDD7
TVDD6
TVDD5
TVDD4
TVDD3
TVDD2
TVDD1
TVDD0
AB13
V21
T21
N22
H22
E21
B13
B10
D2
J3
N2
T3
U4
AB10
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.
RVDD13
RVDD12
RVDD11
RVDD10
RVDD9
RVDD8
RVDD7
RVDD6
RVDD5
RVDD4
RVDD3
RVDD2
RVDD1
RVDD0
AC15
AA23
T22
R23
F23
E22
A15
A8
E2
F1
R1
T2
Y2
AB9
PWR
Receive Analog Power Supply (3.3V ±5%)
For long haul applications, 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.
DVDD
DVDD
DVDD
DVDD
DVDD
DVDD
J2
V2
D12
AA12
U21
K23
PWR
NOTE: In long haul applications where the receive inputs can be severely
attenuated, it is critical to have a clean power supply design and clean
PCB layout with respect to RVDD. It is highly recommended that
RVDD be isolated from DVDD and TVDD.
Digital Power Supply (3.3V ±5%)
DVDD should be isolated from the analog 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. Every two DVDD power supply pins should
be bypassed to ground through at least one 0.1µF capacitor.
10
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
POWER AND GROUND
NAME
PIN
TYPE
DESCRIPTION
DVDD_DRV
DVDD_DRV
DVDD_DRV
DVDD_DRV
DVDD_DRV
DVDD_DRV
DVDD_PRE
DVDD_PRE
DVDD_PRE
DVDD_PRE
DVDD_UP
C21
AC2
K3
D9
AA16
U22
C3
Y5
D20
Y20
AA15
PWR
Digital Power Supply (3.3V ±5%)
DVDD should be isolated from the analog 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. Every two DVDD power supply pins should
be bypassed to ground through at least one 0.1µF capacitor.
AVDD_BIAS
AVDD_PLL22
AVDD_PLL21
AVDD_PLL12
AVDD_PLL11
K4
C15
B15
AB16
AC16
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.
TGND13
TGND12
TGND11
TGND10
TGND9
TGND8
TGND7
TGND6
TGND5
TGND4
TGND3
TGND2
TGND1
TGND0
Y13
V20
R20
M20
J20
F20
D13
D11
F4
J4
M4
R4
V4
Y11
GND
Transmit Analog Ground
It’s recommended that all ground pins of this device be tied together.
RGND13
RGND12
RGND11
RGND10
RGND9
RGND8
RGND7
RGND6
RGND5
RGND4
RGND3
RGND2
RGND1
RGND0
AC12
W22
V23
M23
J23
C23
A12
A11
C1
J1
M1
V1
W2
AC11
GND
Receive Analog Ground
It’s recommended that all ground pins of this device be tied together.
11
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
POWER AND GROUND
NAME
PIN
TYPE
DESCRIPTION
DGND
DGND
DGND
DGND
DGND
DGND
L2
T4
C12
Y12
U20
L23
GND
Digital Ground
It’s recommended that all ground pins of this device be tied together.
DGND_DRV
DGND_DRV
DGND_DRV
DGND_DRV
DGND_DRV
DGND_DRV
DGND_PRE
DGND_PRE
DGND_PRE
DGND_PRE
DGND_UP
B2
U3
A16
AA8
L21
AB23
L4
D15
AB8
L20
AB15
GND
Digital Ground
It’s recommended that all ground pins of this device be tied together.
AGND_BIAS
AGND_PLL22
AGND_PLL21
AGND_PLL12
AGND_PLL11
L3
C9
C8
Y9
AC8
GND
Analog Ground
It’s recommended that all ground pins of this device be tied together.
NAME
PIN
TYPE
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
A1
B1
K1
L1
AA1
AC1
K2
D3
E4
K20
D21
K21
K22
L22
AA22
B23
NC
NO CONNECTS
DESCRIPTION
No Connect
This pin can be left floating or tied to ground.
12
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
1.0 CLOCK SYNTHESIZER
In system design, fewer clocks on the network card could reduce noise and interference. Common clock
references such as 8kHz are readily available to network designers. Network cards that support both T1 and
E1 modes must be able to produce 1.544MHz and 2.048MHz transmission data. The XRT83L314 has a built
in clock synthesizer that requires only one input clock reference by programming CLKSEL[3:0] in the
appropriate global register. A list of the input clock options is shown in Table 1.
TABLE 1: INPUT CLOCK SOURCE SELECT
CLKSEL[3:0]
INPUT CLOCK REFERENCE
0h (0000)
2.048 MHz
1h (0001)
1.544MHz
2h (0010)
8 kHz
3h (0011)
16 kHz
4h (0100)
56 kHz
5h (0101)
64 kHz
6h (0110)
128 kHz
7h (0111)
256 kHz
8h (1000)
4.096 MHz
9h (1001)
3.088 MHz
Ah (1010)
8.192 MHz
Bh (1011)
6.176 MHz
Ch (1100)
16.384 MHz
Dh (1101)
12.352 MHz
Eh (1110)
2.048 MHz
Fh (1111)
1.544 MHz
The single input clock reference is used to generate multiple timing references. The first objective of the clock
synthesizer is to generate 1.544MHz and 2.048MHz for each of the 14 channels. This allows each channel to
operate in either T1 or E1 mode independent from the other channels. The state of the equalizer control bits in
the appropriate channel registers determine whether the LIU operates in T1 or E1 mode. The second objective
is to generate additional output clock references for system use. The available output clock references are
shown in Figure 2.
13
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
FIGURE 2. SIMPLIFIED BLOCK DIAGRAM OF THE CLOCK SYNTHESIZER
Input Clock
Clock
Synthesizer
Internal
Reference
1.544MHz
2.048MHz
8kHzOUT
1.544Mhz
MCLKE1out
2.048MHz
MCLKE1Nout
MCLKT1Nout
1.1
8kHz
MCLKT1out
Programmable
Programmable
2.048/4.096/8.192/16.384 MHz
1.544/3.088/6.176/12.352MHz
ALL T1/E1 Mode
To reduce system noise and power consumption, the XRT83L314 offers an ALL T1/E1 mode. Since most line
card designs are configured to operate in T1 or E1 only, the LIU can be selected to shut off the timing
references for the mode not being used by programming the appropriate global register. By default the ALL
T1/E1 mode is enabled (ALLT1/E1 bit = "0"). If the LIU is configured for T1, all E1 clock references and the
8kHz reference are shut off internally to the chip. This reduces the amount of internal clocks switching within
the LIU, hence reducing noise and power consumption. In E1 mode, the T1 clock references are internally
shut off, however the 8kHz reference is available. To disable this feature, the ALLT1/E1 bit must be set to a "1"
in the appropriate global register.
2.0 RECEIVE PATH LINE INTERFACE
The receive path of the XRT83L314 LIU consists of 14 independent T1/E1/J1 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 3.
FIGURE 3. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE PATH
RCLK
RPOS
RNEG
HDB3/B8ZS
Decoder
Rx Jitter
Attenuator
Clock & Data
Recovery
Peak Detector
& Slicer
Rx Equalizer
Rx Equalizer
Control
14
RTIP
RRING
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.1
2.1.1
Line Termination (RTIP/RRING)
CASE 1: Internal Termination
The input stage of the receive path accepts standard T1/E1/J1 twisted pair or E1 coaxial cable 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 (along with the transmit termination) impedance is
selected by programming TERSEL[1:0] to match the line impedance. Selecting the internal impedance is
shown in Table 2.
TABLE 2: SELECTING THE INTERNAL IMPEDANCE
TERSEL[1:0]
RECEIVE TERMINATION
0h (00)
100Ω
1h (01)
110Ω
2h (10)
75Ω
3h (11)
120Ω
The XRT83L314 has the ability to switch the internal termination to "High" impedance by programming
RxTSEL in the appropriate channel register. For internal termination, set RxTSEL to "1". By default, RxTSEL
is set to "0" ("High" impedance). For redundancy applications, a dedicated hardware pin (RxTSEL) is also
available to control the receive termination for all channels simultaneously. This hardware pin takes priority
over the register setting if RxTCNTL is set to "1" in the appropriate global register. If RxTCNTL is set to "0", the
state of this pin is ignored. See Figure 4 for a typical connection diagram using the internal termination.
FIGURE 4. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION
XRT83L314 LIU
RTIP
Receiver
Input
1:1
Line Interface T1/E1/J1
RRING
One Bill of Materials
Internal Impedance
15
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.1.2
CASE 2: Internal Termination With One External Fixed Resistor for All Modes
Along with the internal termination, a high precision external fixed resistor can be used to optimize the return
loss. This external resistor can be used for all modes of operation ensuring one bill of materials. There are
three resistor values that can be used by setting the RxRES[1:0] bits in the appropriate channel register.
Selecting the value for the external fixed resistor is shown in Table 3.
TABLE 3: SELECTING THE VALUE OF THE EXTERNAL FIXED RESISTOR
RXRES[1:0]
EXTERNAL FIXED RESISTOR
0h (00)
None
1h (01)
240Ω
2h (10)
210Ω
3h (11)
150Ω
By default, RxRES[1:0] is set to "None" for no external fixed resistor. If an external fixed resistor is used, the
XRT83L314 uses the parallel combination of the external fixed resistor and the internal termination as the input
impedance. See Figure 5 for a typical connection diagram using the external fixed resistor.
NOTE: Without the external resistor, the XRT83L314 meets all return loss specifications. This mode was created to add
flexibility for optimizing return loss by using a high precision external resistor.
FIGURE 5. TYPICAL CONNECTION DIAGRAM USING ONE EXTERNAL FIXED RESISTOR
XRT83L314 LIU
RTIP
Receiver
Input
RRING
1:1
R
R=240Ω, 210Ω, or 150Ω
Internal Impedance
16
Line Interface T1/E1/J1
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.2
Equalizer Control
The main objective of the equalizer is to amplify an input attenuated signal to a pre-determined amplitude that
is acceptable to the peak detector circuit. Using feedback from the peak detector, the equalizer will gain the
input up to the maximum value specified by the equalizer control bits, in the appropriate channel register,
normalizing the signal. Once the signal has reached the pre-determined amplitude, the signal is then
processed within the peak detector and slicer circuit. A simplified block diagram of the equalizer and peak
detector is shown in Figure 6.
FIGURE 6. SIMPLIFIED BLOCK DIAGRAM OF THE EQUALIZER AND PEAK DETECTOR
Peak
Detector &
Slicer
RTIP
Rx Equalizer
RRING
Rx Equalizer
Control
2.3
Cable Loss Indicator
The ability to monitor the cable loss attenuation of the receiver inputs is a valuable feature. The XRT83L314
contains a per channel, read only register for cable loss indication. CLOS[5:0] is a 6-Bit binary word that
reports the value of cable loss in 1dB steps. An example of -25dB cable loss attenuation is shown in Figure 7.
FIGURE 7. SIMPLIFIED BLOCK DIAGRAM OF THE CABLE LOSS INDICATOR
XRT83L314
-25dB Attenuated
Signal
-25dB of Cable
Loss
Equalizer and
Peak Detector
Read Only
CLOS[5:0] = 0x19h
(25dec = 19hex)
17
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.4
Equalizer Attenuation Flag
The ability to detect the amount of cable loss on the receiver inputs is enhanced by having the ability to
generate an interrupt by programming a pre-determined value for cable loss into the EQFLAG[5:0] global
register. This is particularly useful in long haul applications where it is necessary for the LIU to generate an
interrupt for a cable loss which is lower than the declaration of the RLOS feature (see the RLOS section in this
datasheet). If the contents of the EQFLAG[5:0] register bits are equal to or less than the contents in the cable
loss indicator bits CLOS[5:0] for a given channel, an interrupt will be generated (if enabled in the appropriate
channel register and GIE is to "1"). Using the same example in Figure 7, a simplified block diagram of the
equalizer flag is shown in Figure 8.
FIGURE 8. SIMPLIFIED BLOCK DIAGRAM OF THE EQUALIZER ATTENUATION FLAG
Receiver Inputs
RTIP/RRING
XRT83L314
-25dB of Cable
Loss
Equalizer and
Peak Detector
Read Only
CLOS[5:0] = 0x19h
If (CLOS = EQFLAG)
Generate an Interrupt
EQFLAG[5:0] = 0x19h
Programmable
2.5
Peak Detector and Slicer
The peak detector provides feedback to the equalizer control circuit until the amplitude of the incoming signal is
at an appropriate level. Once this level is obtained, the slicer identifies the incoming signal as a "1" and passes
the raw data to the clock and data recovery circuit. The slicer threshold is selected by programming SL[1:0] in
the appropriate global register. Selecting the slicer level is shown in Table 4.
TABLE 4: SELECTING THE SLICER LEVEL FOR THE PEAK DETECTOR
SL[1:0]
SLICER LEVEL
0h (00)
50%
1h (01)
45%
2h (10)
55%
3h (11)
68%
18
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14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.6
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. This allows for multichannel T1/E1/J1 signals to arrive from different timing sources and remain independent. In the absence of an
incoming signal, RCLK maintains its timing by using the internal master clock 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 RCLKE to "1" in the appropriate global register. Figure 9 is a
timing diagram of the receive data updated on the rising edge of RCLK. Figure 10 is a timing diagram of the
receive data updated on the falling edge of RCLK. The timing specifications are shown in Table 5.
FIGURE 9. RECEIVE DATA UPDATED ON THE RISING EDGE OF RCLK
R CLKR
R DY
R CLKF
R C LK
RPOS
or
RNEG
ROH
FIGURE 10. RECEIVE DATA UPDATED ON THE FALLING EDGE OF RCLK
RCLKF
RDY
RCLK
RPOS
or
RNEG
ROH
19
RCLKR
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 5: 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
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
2.6.1
Receive Sensitivity
To meet Long Haul receive sensitivity requirements, the XRT83L314 can accept T1/E1/J1 signals that have
been attenuated by 43dB cable attenuation in E1 mode or 36dB cable attenuation in T1 mode without
experiencing bit errors, LOF, pattern synchronization, etc. Short haul specifications are for 12dB of flat loss in
E1 mode. T1 specifications are 655 feet of cable loss along with 6dB of flat loss in T1 mode. The XRT83L314
can tolerate cable loss and flat loss beyond the industry specifications. The receive sensitivity in the short haul
mode is approximately 4,000 feet without experiencing bit errors, LOF, pattern synchronization, etc. Although
data integrity is maintained, the RLOS function (if enabled) will report an RLOS condition according to the
receiver loss of signal section in this datasheet. The test configuration for measuring the receive sensitivity is
shown in Figure 11.
FIGURE 11. TEST CONFIGURATION FOR MEASURING RECEIVE SENSITIVITY
W&G ANT20
Rx
Tx
Cable Loss
Network
Analyzer
Flat Loss
Rx
Tx
E1 = PRBS 215 - 1
T1 = PRBS 223 - 1
20
External Loopback
XRT83L314
14-Channel
Long Haul LIU
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.6.2
Interference Margin
The interference margin for the XRT83L314 will be added when the first revision of silicon arrives. The test
configuration for measuring the interference margin is shown in Figure 12.
FIGURE 12. TEST CONFIGURATION FOR MEASURING INTERFERENCE MARGIN
E1 = 1,024kHz
T1 = 772kHz
Sinewave
Generator
Flat Loss
E1 = PRBS 215 - 1
T1 = PRBS 223 - 1
W&G ANT20
Network
Analyzer
Rx
Tx
Rx
2.6.3
External Loopback
Cable Loss
Tx
XRT83L314
14-Channel LIU
General Alarm Detection and Interrupt Generation
The receive path detects EQFLAG, RLOS, AIS, QRPD, NCLD, and FLS. 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 (it
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).
The interrupts are categorized in a hierarchical process block. Figure 13 is a simplified block diagram of the
interrupt generation process.
FIGURE 13. INTERRUPT GENERATION PROCESS BLOCK
Global Interrupt
Enable (GIE="1")
Global Channel Interrupt Status
(Indicates Which Channel(s) Experienced a Change in
Status)
Individual Alarm Status Change
(Indicates Which Alarm Experienced a Change)
Individual Alarm Indication
(Indicates the Alarm Condition Active/Inactive)
NOTE: The interrupt pin is an open-drain output that requires a 10kΩ external pull-up resistor.
2.6.3.1
RLOS (Receiver Loss of Signal)
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14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
In T1 mode, RLOS is declared if an incoming signal has no transitions over a period of 175 +/-75 contiguous
pulse intervals. However, the XRT83L314 LIU has a built in analog RLOS so that the user can be notified
when the amplitude of the incoming signal has been attenuated -9dB below the equalizer gain setting. For
example: In T1 or E1 short haul mode, the equalizer gain setting is 15dB. Once the input reaches an
amplitude of -24dB below nominal, the LIU will declare RLOS. The RLOS circuitry clears when the input
reaches +3dB relative to where it was declared. This +3dB value is a pre-determined hysteresis so that
transients will not cause the RLOS to clear. In E1 mode, RLOS is declared if an incoming signal has no
transitions for N consecutive pulse intervals, where 10≤N≤255. According to G.775, no transitions in E1 mode
is defined between -9dB and -35dB below nominal. Figure 14 is a simplified block diagram of the analog
RLOS function. Table 6 summarizes the analog RLOS values for the different equalizer gain settings.
FIGURE 14. ANALOG RECEIVE LOS OF SIGNAL FOR T1/E1/J1
Normalized up to EQC[4:0] Setting
-9dB
Clear LOS
+3dB
Declare LOS
Declare LOS
+3dB
Clear LOS
-9dB
Normalized up to EQC[4:0] Setting
TABLE 6: ANALOG RLOS DECLARE/CLEAR (TYPICAL VALUES) FOR T1/E1
GAIN SETTING
DECLARE
CLEAR
15dB (Short Haul Mode)
-24dB
-21dB
29dB (Monitoring Gain Mode)
-38dB
-35dB
36dB (Long Haul Mode)
-45dB
-42dB
45dB (Long Haul Mode)
-54dB
-51dB
NOTE: For programming the equalizer gain setting on a per channel basis, see the microprocessor register map for details.
2.6.3.2
EXLOS (Extended Loss of Signal)
By enabling the extended loss of signal by programming the appropriate channel register, the digital RLOS is
extended to count 4,096 consecutive zeros before declaring RLOS in T1 and E1 mode. By default, EXLOS is
disabled and RLOS operates in normal mode.
2.6.3.3
AIS (Alarm Indication Signal)
The XRT83L314 adheres to the ITU-T G.775 specification for an all ones pattern. The alarm indication signal
is set to "1" if an all ones pattern (at least 99.9% ones density) is present for T, where T is 3ms to 75ms in T1
mode. AIS will clear when the ones density is not met within the same time period T. In E1 mode, the AIS is
set to "1" if the incoming signal has 2 or less zeros in a 512-bit window. AIS will clear when the incoming signal
has 3 or more zeros in the 512-bit window.
2.6.3.4
NLCD (Network Loop Code Detection)
The Network Loop Code Detection can be programmed to detect a Loop-Up, Loop-Down, or Automatic Loop
Code. If the network loop code detection is programmed for Loop-Up, the NLCD will be set "High" if a
repeating pattern of "00001" occurs for more than 5 seconds. If the network loop code detection is
programmed for Loop-Down, the NLCD will be set "High" if a repeating pattern of "001" occurs for more than 5
22
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
seconds. If the network loop code detection is programmed for automatic loop code, the LIU is configured to
detect a Loop-Up code. If a Loop-Up code is detected for more than 5 seconds, the XRT83L314 will
automatically program the channel into a remote loopback mode. The LIU will remain in remote loopback even
if the Loop-Up code disappears. The channel will continue in remote loop back until a Loop-Down code is
detected for more than 5 seconds (or, if the automatic loop code is disabled) and then automatically return to
normal operation with no loop back. The process of the automatic loop code detection is shown in Figure 15.
FIGURE 15. PROCESS BLOCK FOR AUTOMATIC LOOP CODE DETECTION
No
Loop-Up
Code for
5 sec?
Yes
Automatic Remote
Loopback
No
Loop-Down
Code for
5 sec?
Yes
23
Disable Remote
Loopback
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.6.3.5
FLSD (FIFO Limit Status Detection)
The purpose of the FIFO limit status is to indicate when the Read and Write FIFO pointers are within a predetermined range (over-flow or under-flow indication). The FLSD is set to "1" if the FIFO Read and Write
Pointers are within ±3-Bits.
2.6.3.6
LCV/OFD (Line Code Violation / Counter Overflow Detection)
The LIU contains 14 independent, 16-bit LCV counters. When the counters reach full-scale, they remain
saturated at FFFFh until they are reset globally or on a per channel basis. For performance monitoring, the
counters can be updated globally or on a per channel basis to place the contents of the counters into holding
registers. The LIU uses an indirect address bus to access a counter for a given channel. Once the contents of
the counters have been placed in the holding registers, they can be individually read out from register 0xE8h 8bits at a time according to the BYTEsel bit in the appropriate global register. By default, the LSB is placed in
register 0xE8h until the BYTEsel is pulled "High" where upon the MSB will be placed in the register for read
back. Once both bytes have been read, the next channel may be selected for read back.
By default, The LCV/OFD will be set to a "1" if the receiver is currently detecting line code violations or
excessive zeros for HDB3 (E1 mode) or B8ZS (T1 mode). In AMI mode, the LCVD will be set to a "1" if the
receiver is currently detecting bipolar violations or excessive zeros. However, if the LIU is configured to
monitor the 16-bit LCV counter by programming the appropriate global register, the LCV/OFD will be set to a
"1" if the counter saturates.
2.7
Receive Jitter Attenuator
The receive path has a dedicated jitter attenuator that reduces 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. In T1 mode, the bandwidth of the JA is always set to 3Hz. In E1 mode, the bandwidth is
programmable to either 10Hz or 1.5Hz (1.5Hz automatically selects the 64-Bit FIFO depth). The JA has a
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 transmit path has
a dedicated jitter attenuator to smooth out the gapped clock. See the Transmit Section of this datasheet.
2.8
HDB3/B8ZS Decoder
In single rail mode, RPOS can decode AMI or HDB3/B8ZS signals. For E1 mode, HDB3 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 prevent a DC component. In T1 mode, 8 successive zeros are replaced with OOOVBOVB. If the
HDB3/B8ZS decoder is selected, the receive path removes the V and B pulses so that the original data is
output to RPOS.
24
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
2.9
RPOS/RNEG/RCLK
The digital output data can be programmed to either single rail or dual rail formats. Figure 16 is a timing
diagram of a repeating "0011" pattern in single-rail mode. Figure 17 is a timing diagram of the same fixed
pattern in dual rail mode.
FIGURE 16. SINGLE RAIL MODE WITH A FIXED REPEATING "0011" PATTERN
0
0
1
1
0
RCLK
RPOS
FIGURE 17. DUAL RAIL MODE WITH A FIXED REPEATING "0011" PATTERN
0
0
1
1
0
RCLK
RPOS
RNEG
2.10
RxMUTE (Receiver LOS with Data Muting)
The receive muting function can be selected by setting RxMUTE to "1" in the appropriate global register. If
selected, any channel that experiences an RLOS condition will automatically pull RPOS and RNEG "Low" to
prevent data chattering. If RLOS does not occur, the RxMUTE will remain inactive until an RLOS on a given
channel occurs. The default setting for RxMUTE is "0" which is disabled. A simplified block diagram of the
RxMUTE function is shown in Figure 18.
FIGURE 18. SIMPLIFIED BLOCK DIAGRAM OF THE RXMUTE FUNCTION
RPOS
RNEG
RxMUTE
RLOS
25
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
3.0 TRANSMIT PATH LINE INTERFACE
The transmit path of the XRT83L314 LIU consists of 14 independent T1/E1/J1 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 19.
FIGURE 19. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT PATH
TCLK
TPOS
TNEG
3.1
HDB3/B8ZS
Encoder
Tx Jitter
Attenuator
Timing
Control
Tx Pulse Shaper
& Pattern Gen
TTIP
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 has
no function and can be left unconnected. The XRT83L314 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 TCLKE to "1" in the appropriate global register. Figure 20 is a timing diagram of the transmit input
data sampled on the falling edge of TCLK. Figure 21 is a timing diagram of the transmit input data sampled on
the rising edge of TCLK. The timing specifications are shown in Table 7.
FIGURE 20. TRANSMIT DATA SAMPLED ON FALLING EDGE OF TCLK
TCLKR
TCLKF
TCLK
TPOS
or
TNEG
TSU
THO
FIGURE 21. TRANSMIT DATA SAMPLED ON RISING EDGE OF TCLK
TCLKF
TCLK
TPOS
or
TNEG
TSU
THO
26
TCLKR
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 7: 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
3.2
HDB3/B8ZS Encoder
In single rail mode, the LIU can encode the TPOS input signal to AMI or HDB3/B8ZS data. In E1 mode and
HDB3 encoding 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 8. In T1 mode and B8ZS encoding selected, an
input data sequence with eight or more consecutive zeros will be replaced using the B8ZS encoding rule. An
example with Bipolar with 8 Zero Substitution is shown in Table 9.
TABLE 8: EXAMPLES OF HDB3 ENCODING
NUMBER OF PULSES BEFORE
NEXT 4 ZEROS
Input
0000
HDB3 (Case 1)
Odd
000V
HDB3 (Case 2)
Even
B00V
TABLE 9: EXAMPLES OF B8ZS ENCODING
CASE 1
PRECEDING PULSE
NEXT 8 BITS
Input
+
00000000
B8ZS
AMI Output
000VB0VB
+
000+-0-+
Case 2
Input
-
B8ZS
AMI Output
00000000
000VB0VB
-
27
000-+0+-
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
3.3
Transmit Jitter Attenuator
The XRT83L314 LIU is ideal for multiplexer or mapper applications where the network data crosses multiple
timing domains. As the higher data rates are de-multiplexed down to T1 or E1 data, stuffing bits are typically
removed which can leave gaps in the incoming data stream. The transmit path has a dedicated jitter
attenuator with a 32-Bit or 64-Bit FIFO that is used to smooth the gapped clock into a steady T1 or E1 output.
The maximum gap width of the 14-Channel LIU is shown in Table 10.
TABLE 10: 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 receive path has a dedicated jitter attenuator. See the Receive
Section of this datasheet.
3.4
TAOS (Transmit All Ones)
The XRT83L314 has the ability to transmit all ones on a per channel basis by programming the appropriate
channel register. This function takes priority over the digital data present on the TPOS/TNEG inputs. For
example: If a fixed "0011" pattern is present on TPOS in single rail mode and TAOS is enabled, the transmitter
will output all ones. In addition, if digital or dual loopback is selected, the data on the RPOS output will be
equal to the data on the TPOS input. Figure 22 is a diagram showing the all ones signal at TTIP and TRING.
FIGURE 22. TAOS (TRANSMIT ALL ONES)
1
1
1
TAOS
3.5
Transmit Diagnostic Features
In addition to TAOS, the XRT83L314 offers multiple diagnostic features for analyzing network integrity such as
ATAOS, Network Loop Code generation, and QRSS on a per channel basis by programming the appropriate
registers. These diagnostic features take priority over the digital data present on TPOS/TNEG inputs. The
transmitters will send the diagnostic code to the line and will be maintained in the digital loopback if selected.
When the LIU is responsible for sending diagnostic patterns, the LIU is automatically placed in the single rail
mode.
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
3.5.1
ATAOS (Automatic Transmit All Ones)
If ATAOS is selected by programming the appropriate global register, an AMI all ones signal will be transmitted
for each channel that experiences an RLOS condition. If RLOS does not occur, the ATAOS will remain inactive
until an RLOS on a given channel occurs. A simplified block diagram of the ATAOS function is shown in
Figure 23.
FIGURE 23. SIMPLIFIED BLOCK DIAGRAM OF THE ATAOS FUNCTION
TTIP
Tx
TRING
TAOS
ATAOS
RLOS
3.5.2
Network Loop Up Code
By setting the LIU to generate a NLUC, the transmitters will send out a repeating "00001" pattern. The output
waveform is shown in Figure 24.
FIGURE 24. NETWORK LOOP UP CODE GENERATION
1
0
0
0
0
1
0
0
0
0
1
Network
Loop-Up
Code
3.5.3
Network Loop Down Code
By setting the LIU to generate a NLDC, the transmitters will send out a repeating "001" pattern. The output
waveform is shown in Figure 25.
FIGURE 25. NETWORK LOOP DOWN CODE GENERATION
1
0
0
1
0
Network
Loop-Down
Code
29
0
1
0
0
1
0
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3.5.4
QRSS Generation
The XRT83L314 can transmit a QRSS random sequence to a remote location from TTIP/TRING.
polynomial is shown in Table 11.
The
TABLE 11: RANDOM BIT SEQUENCE POLYNOMIALS
3.6
RANDOM PATTERN
T1
E1
QRSS
220 - 1
215 - 1
Transmit Pulse Shaper and Filter
If TCLK is not present, pulled "Low", or pulled "High" the transmitter outputs at TTIP/TRING will automatically
send an all ones or an all zero signal to the line by programming the appropriate global register. By default, the
transmitters will send all zeros. To send all ones, the TCLKCNL bit must be set "High".
3.6.1
T1 Long Haul Line Build Out (LBO)
The long haul transmitter output pulses are generated using a 7-Bit internal DAC (6-Bits plus the MSB sign bit).
The line build out can be set to -7.5dB, -15dB, or -22dB cable attenuation by programming the appropriate
channel register. The long haul LBO consist of 32 discrete time segments extending over four consecutive
periods of TCLK. As the LBO attenuation is increased, the pulse amplitude is reduced so that the waveform
complies with ANSI T1.403 specifications. A long haul pulse with -7.5dB attenuation is shown in Figure 26, a
pulse with -15dB attenuation is shown in Figure 27, and a pulse with -22.5dB attenuation is shown in
Figure 28.
FIGURE 26. LONG HAUL LINE BUILD OUT WITH -7.5DB ATTENUATION
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FIGURE 27. LONG HAUL LINE BUILD OUT WITH -15DB ATTENUATION
FIGURE 28. LONG HAUL LINE BUILD OUT WITH -22.5DB ATTENUATION
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3.6.2
T1 Short Haul Line Build Out (LBO)
The short haul transmitter output pulses are generated using a 7-Bit internal DAC (6-Bit plus the MSB sign bit).
The line build out can be set to interface to five different ranges of cable attenuation by programming the
appropriate channel register. The pulse shape is divided into eight discrete time segments which are set to
fixed values to comply with the pulse template. To program the eight segments individually to optimize a
special line build out, see the arbitrary pulse section of this datasheet. The short haul LBO settings are shown
in Table 12
TABLE 12: SHORT HAUL LINE BUILD OUT
3.6.3
LBO SETTING EQC[4:0]
RANGE OF CABLE ATTENUATION
08h (01000)
0 - 133 Feet
09h (01001)
133 - 266 Feet
0Ah (01010)
266 - 399 Feet
0Bh (01011)
399 - 533 Feet
0Ch (01100)
533 - 655 Feet
Arbitrary Pulse Generator For T1 and E1
The arbitrary pulse generator divides the pulse into eight individual segments. Each segment is set by a 7-Bit
binary word by programming the appropriate channel register. This allows the system designer to set the
overshoot, amplitude, and undershoot for a unique line build out. The MSB (bit 7) is a sign-bit. If the sign-bit is
set to "0", the segment will move in a positive direction relative to a flat line (zero) condition. If this sign-bit is
set to "1", the segment will move in a negative direction relative to a flat line condition. The resolution of the
DAC is typically 60mV per LSB. Thus, writing 7-bit = 1111111 will clamp the output at either voltage rail
corresponding to a maximum amplitude. A pulse with numbered segments is shown in Figure 29.
FIGURE 29. ARBITRARY PULSE SEGMENT ASSIGNMENT
1
2
3
Segment
1
2
3
4
5
6
7
8
4
Register
0xn8
0xn9
0xna
0xnb
0xnc
0xnd
0xne
0xnf
8
7
6
5
NOTE: By default, the arbitrary segments are programmed to 0x00h. The transmitter outputs will result in an all zero
pattern to the line interface.
3.7
DMO (Digital 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 clock 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
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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).
3.8
Line Termination (TTIP/TRING)
The output stage of the transmit path generates standard return-to-zero (RZ) signals to the line interface for
T1/E1/J1 twisted pair or E1 coaxial cable. 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 transmitter outputs only require one DC blocking
capacitor of 0.68µF. For redundancy applications (or simply to tri-state the transmitters), set TxTSEL to a "1" in
the appropriate channel register. A typical transmit interface is shown in Figure 30.
FIGURE 30. TYPICAL CONNECTION DIAGRAM USING INTERNAL TERMINATION
XRT83L314 LIU
TTIP
Transmitter
Output
1:2
C=0.68uF
Line Interface T1/E1/J1
TRING
One Bill of Materials
Internal Impedance
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4.0 T1/E1 APPLICATIONS
This applications section describes common T1/E1 system considerations along with references to application
notes available for reference where applicable.
4.1
Loopback Diagnostics
The XRT83L314 supports several loopback modes for diagnostic testing. The following section describes the
local analog loopback, remote loopback, digital loopback, and dual loopback modes.
4.1.1
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 31.
FIGURE 31. SIMPLIFIED BLOCK DIAGRAM OF LOCAL ANALOG LOOPBACK
NLC/PRBS/QRSS
TAOS
TCLK
TPOS
TNEG
Encoder
JA
Timing
Control
RCLK
RPOS
RNEG
Decoder
JA
Data and
Clock
Recovery
TTIP
TRING
Tx
RTIP
RRING
Rx
NOTE: The transmit diagnostic features such as TAOS, NLC generation, and QRSS take priority over the transmit input
data at TCLK/TPOS/TNEG.
4.1.2
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 remote loopback includes the Receive JA (if enabled). 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 32.
FIGURE 32. SIMPLIFIED BLOCK DIAGRAM OF REMOTE LOOPBACK
NLC/PRBS/QRSS
TAOS
TCLK
TPOS
TNEG
Encoder
JA
Timing
Control
RCLK
RPOS
RNEG
Decoder
JA
Data and
Clock
Recovery
34
TTIP
TRING
Tx
Rx
RTIP
RRING
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4.1.3
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 digital loopback mode includes the Transmit JA (if enabled). 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 33.
FIGURE 33. SIMPLIFIED BLOCK DIAGRAM OF DIGITAL LOOPBACK
NLC/PRBS/QRSS
4.1.4
TAOS
TCLK
TPOS
TNEG
Encoder
JA
Timing
Control
RCLK
RPOS
RNEG
Decoder
JA
Data and
Clock
Recovery
TTIP
TRING
Tx
Rx
RTIP
RRING
Dual Loopback
With dual loopback activated, the remote loopback is combined with the digital loopback. A simplified block
diagram of dual loopback is shown in Figure 34.
FIGURE 34. SIMPLIFIED BLOCK DIAGRAM OF DUAL LOOPBACK
NLC/PRBS/QRSS
TAOS
TCLK
TPOS
TNEG
Encoder
JA
Timing
Control
RCLK
RPOS
RNEG
Decoder
JA
Data and
Clock
Recovery
35
Tx
Rx
TTIP
TRING
RTIP
RRING
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4.2
84-Channel T1/E1 Multiplexer/Mapper Applications
The XRT83L314 has the capability of providing the necessary chip selects for multiple 14-channel LIU devices.
The LIU is responsible for selecting itself, up to 5 additional LIU devices, or all 6 devices simultaneously for
permitting access to internal registers. The state of the chip select output pins is determined by a chip select
decoder controlled by the 3 MSBs of the address bus ADDR[10:8]. Only one LIU (Master) requires the
ADDR[10:8]. The other 5 LIU devices use the 8 LSBs for the direct address bus ADDR[7:0]. Figure 35 is a
simplified block diagram of connecting six 14-channel LIU devices for 84-channel applications. Selection of
the chip select outputs using ADDR[10:8] is shown in Table 13.
FIGURE 35. SIMPLIFIED BLOCK DIAGRAM OF AN 84-CHANNEL APPLICATION
Master
CS[4:0]
CS
XRT83L314
Slave
1
Slave
CS
XRT83L314
CS
XRT83L314
2
Slave
3
Slave
CS
XRT83L314
4
Data [7:0]
Chip Address A[10:8]
TABLE 13: CHIP SELECT ASSIGNMENTS
ADDR[10:8]
ACTIVE CHIP SELECT
0h (000)
Current Device (Master)
1h (001)
Chip 1
2h (010)
Chip 2
3h (011)
Chip 3
4h (100)
Chip 4
5h (101)
Chip 5
6h (110)
Reserved
7h (111)
All Devices Active
Slave
XRT83L314
5
Address A[7:0]
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CS
XRT83L314
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4.3
Line Card Redundancy
Telecommunication system design requires signal integrity and reliability. When a T1/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
XRT83L314 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 XRT83L314 reports the alarm to the individual status registers on a
per channel basis. However, for redundancy applications, an RLOS or DMO alarm can be used to initiate an
automatic switch to the back up card. For this application, two global pins RLOS and DMO are used to indicate
that one of the 14-channels has an RLOS or DMO condition.
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
4.3.1
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.
4.3.2
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, T1/E1/J1. A 0.68uF capacitor is used in series with TTIP for blocking DC bias. See
Figure 36. for a simplified block diagram of the transmit section for a 1:1 and 1+1 redundancy.
FIGURE 36. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR 1:1 AND 1+1 REDUNDANCY
Backplane Interface
Primary Card
XRT83L314
1:2
Tx
0.68uF
T1/E1 Line
Internal Impedence
Backup Card
XRT83L314
1:2
Tx
0.68uF
Internal Impedence
4.3.3
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, T1/E1/J1. To swap the primary card, set the backup
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card to internal impedance, then the primary card to "High" impedance. See Figure 37. for a simplified block
diagram of the receive section for a 1:1 redundancy scheme.
FIGURE 37. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR 1:1 AND 1+1 REDUNDANCY
Backplane Interface
Primary Card
XRT83L314
1:1
T1/E1 Line
Rx
Internal Impedence
XRT83L314
Backup Card
1:1
Rx
"High" Impedence
4.3.4
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.
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4.3.5
Transmit Interface with N+1 Redundancy
For N+1 redundancy, the transmitters on all cards should 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, and tri-state the transmitters on the failed primary card. A 0.68uF capacitor is used in series with TTIP
for blocking DC bias. See Figure 38 for a simplified block diagram of the transmit section for an N+1
redundancy scheme.
FIGURE 38. SIMPLIFIED BLOCK DIAGRAM OF THE TRANSMIT INTERFACE FOR N+1 REDUNDANCY
Backplane Interface
Line Interface Card
Primary Card
XRT83L314
1:2
Tx
0.68uF
T1/E1 Line
Internal
Impedence
Primary Card
XRT83L314
1:2
Tx
0.68uF
T1/E1 Line
Internal
Impedence
Primary Card
XRT83L314
1:2
Tx
0.68uF
T1/E1 Line
Internal
Impedence
Backup Card
XRT83L314
Tx
0.68uF
Internal
Impedence
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4.3.6
Receive Interface with N+1 Redundancy
For N+1 redundancy, the receivers on the primary cards should be programmed for internal impedance. The
receivers on the backup card should be programmed for "High" impedance mode. To swap the primary card,
set the backup card to internal impedance, then the primary card to "High" impedance. See Figure 39 for a
simplified block diagram of the receive section for a N+1 redundancy scheme.
FIGURE 39. SIMPLIFIED BLOCK DIAGRAM OF THE RECEIVE INTERFACE FOR N+1 REDUNDANCY
Backplane Interface
Line Interface Card
Primary Card
XRT83L314
1:1
Rx
T1/E1 Line
Internal
Impedence
Primary Card
XRT83L314
1:1
T1/E1 Line
Rx
Internal
Impedence
Primary Card
XRT83L314
1:1
T1/E1 Line
Rx
Internal
Impedence
Backup Card
XRT83L314
Rx
"High"
Impedence
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4.4
Power Failure Protection
For 1:1 or 1+1 line card redundancy in T1/E1 applications, power failure could cause a line card to change the
characteristics of the line impedance, causing a degradation in system performance. The XRT83L314 was
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.
4.5
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.
4.6
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 XRT83L314’s internal
termination ensures that the line termination meets T1/E1 specifications for 75Ω, 100Ω 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 40.
FIGURE 40. SIMPLIFIED BLOCK DIAGRAM OF A NON-INTRUSIVE MONITORING APPLICATION
XRT83L314
Data Traffic
Line Card Transceiver
Node
XRT83L314
Non-Intrusive Receiver
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5.0 MICROPROCESSOR INTERFACE BLOCK
The Microprocessor Interface section supports communication between the local microprocessor (µP) and the
LIU. The XRT83L314 supports an Intel asynchronous interface, Motorola 68K asynchronous, and a Motorola
Power PC interface. The microprocessor interface is selected by the state of the µPTS[2:0] input pins. Selecting the microprocessor interface is shown in Table 14.
TABLE 14: SELECTING THE MICROPROCESSOR INTERFACE MODE
µPTS[2:0]
MICROPROCESSOR MODE
0h (000)
Intel 68HC11, 8051, 80C188
(Asynchronous)
1h (001)
Motorola 68K (Asynchronous)
7h (111)
Motorola MPC8260, MPC860
Power PC (Synchronous)
The XRT83L314 uses multipurpose pins to configure the device appropriately. The local µP configures the LIU
by writing data into specific addressable, on-chip Read/Write registers. The microprocessor interface provides
the signals which are required for a general purpose microprocessor to read or write data into these registers.
The microprocessor interface also supports polled and interrupt driven environments. A simplified block diagram of the microprocessor is shown in Figure 41.
FIGURE 41. SIMPLIFIED BLOCK DIAGRAM OF THE MICROPROCESSOR INTERFACE BLOCK
CS
WR_R/W
RD_WE
ALE
ADDR[10:0]
DATA[7:0]
µPclk
Microprocessor
Interface
µPType [2:0]
CS5
CS4
CS3
CS2
CS1
Reset
RDY_TA
INT
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5.1 THE MICROPROCESSOR INTERFACE BLOCK SIGNALS
The LIU may be configured into different operating modes and have its performance monitored by software
through a standard microprocessor using data, address and control signals. These interface signals are described below in Table 15, Table 16, and Table 17. The microprocessor interface can be configured to operate
in Intel mode or Motorola mode. When the microprocessor interface is operating in Intel mode, some of the
control signals function in a manner required by the Intel 80xx family of microprocessors. Likewise, when the
microprocessor interface is operating in Motorola mode, then these control signals function in a manner as required by the Motorola Power PC family of microprocessors. (For using a Motorola 68K asynchronous processor, see Figure 44 and Table 20) Table 15 lists and describes those microprocessor interface signals whose
role is constant across the two modes. Table 16 describes the role of some of these signals when the microprocessor interface is operating in the Intel mode. Likewise, Table 17 describes the role of these signals when
the microprocessor interface is operating in the Motorola mode.
TABLE 15: XRT84L314 MICROPROCESSOR INTERFACE SIGNALS THAT EXHIBIT CONSTANT ROLES IN BOTH INTEL
AND MOTOROLA MODES
PIN NAME
TYPE
DESCRIPTION
µPTS[2:0]
I
Microprocessor Interface Mode Select Input pins
These three pins are used to specify the microprocessor interface mode. The relationship
between the state of these three input pins, and the corresponding microprocessor mode is
presented in Table 14.
DATA[7:0]
I/O
ADDR[10:8]
I
Three-Bit Address Bus Inputs
The 3 MSBs of the address bits are used as a chip select decoder. The state of these 3 pins
enable the Chip Selects for additional LIU devices.
NOTE: See the 84-Channel Application Section of this datasheet.
ADDR[7:0]
I
Eight-Bit Address Bus Inputs
The XRT83L314 LIU microprocessor interface uses a direct address bus. This address bus is
provided to permit the user to select an on-chip register for Read/Write access.
CS
I
Chip Select Input
This active low signal selects the microprocessor interface of the XRT83L314 LIU and enables
Read/Write operations with the on-chip register locations.
Bi-Directional Data Bus for register "Read" or "Write" Operations.
TABLE 16: INTEL MODE: MICROPROCESSOR INTERFACE SIGNALS
XRT83L314
INTEL
PIN NAME EQUIVALENT PIN
TYPE
DESCRIPTION
ALE_TS
ALE
I
Address-Latch Enable: This active high signal is used to latch the contents on
the address bus ADDR[7:0]. The contents of the address bus are latched into the
ADDR[7:0] inputs on the falling edge of ALE.
RD_WE
RD
I
Read Signal: This active low input functions as the read signal from the local µP.
When this pin is pulled “Low” (if CS is “Low”) the LIU is informed that a read operation has been requested and begins the process of the read cycle.
WR_R/W
WR
I
Write Signal: This active low input functions as the write signal from the local µP.
When this pin is pulled “Low” (if CS is “Low”) the LIU is informed that a write
operation has been requested and begins the process of the write cycle.
RDY_TA
RDY
O
Ready Output: This active low signal is provided by the LIU device. It indicates
that the current read or write cycle is complete, and the LIU is waiting for the next
command.
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TABLE 17: MOTOROLA MODE: MICROPROCESSOR INTERFACE SIGNALS
XRT83L314
MOTOROLA
PIN NAME EQUIVALENT PIN
TYPE
DESCRIPTION
ALE_TS
TS
I
Transfer Start: This active high signal is used to latch the contents on the
address bus ADDR[7:0]. The contents of the address bus are latched into the
ADDR[7:0] inputs on the falling edge of TS.
WR_R/W
R/W
I
Read/Write: This input pin from the local µP is used to inform the LIU
whether a Read or Write operation has been requested. When this pin is
pulled “High”, WE will initiate a read operation. When this pin is pulled
“Low”, WE will initiate a write operation.
RD_WE
WE
I
Write Enable: This active low input functions as the read or write signal from the
local µP dependent on the state of R/W. When WE is pulled “Low” (If CS
is “Low”) the LIU begins the read or write operation.
No Pin
OE
I
Output Enable: This signal is not necessary for the XRT83L314 to interface to
the MPC8260 or MPC860 Power PCs.
µPCLK
CLKOUT
I
Synchronous Processor Clock: This signal is used as the timing reference for
the Power PC synchronous mode.
RDY_TA
TA
O
Transfer Acknowledge: This active low signal is provided by the LIU device. It
indicates that the current read or write cycle is complete, and the LIU is waiting
for the next command.
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5.2 INTEL MODE PROGRAMMED I/O ACCESS (ASYNCHRONOUS)
If the LIU is interfaced to an Intel type µP, then it should be configured to operate in the Intel mode. Intel type
Read and Write operations are described below.
Intel Mode Read Cycle
Whenever an Intel-type µP wishes to read the contents of a register, it should do the following.
1. Place the address of the target register on the address bus input pins ADDR[10:0].
2. While the µP is placing this address value on the address bus, the address decoding circuitry should
assert the CS pin of the LIU, by toggling it "Low". This action enables further communication between the
µP and the LIU microprocessor interface block.
3. Toggle the ALE input pin "High". This step enables the address bus input drivers, within the microprocessor interface block of the LIU.
4. The µP should then toggle the ALE pin "Low". This step causes the LIU to latch the contents of the address
bus into its internal circuitry. At this point, the address of the register has now been selected.
5. Next, the µP should indicate that this current bus cycle is a Read operation by toggling the RD input pin
"Low". This action also enables the bi-directional data bus output drivers of the LIU.
6. After the µP toggles the Read signal "Low", the LIU will toggle the RDY output pin "Low". The LIU does this
in order to inform the µP that the data is available to be read by the µP, and that it is ready for the next command.
7. After the µP detects the RDY signal and has read the data, it can terminate the Read Cycle by toggling the
RD input pin "High".
NOTE: ALE can be tied “High” if this signal is not available.
The Intel Mode Write Cycle
Whenever an Intel type µP wishes to write a byte or word of data into a register within the LIU, it should do the
following.
1. Place the address of the target register on the address bus input pins ADDR[10:0].
2. While the µP is placing this address value on the address bus, the address decoding circuitry should
assert the CS pin of the LIU, by toggling it "Low". This action enables further communication between the
µP and the LIU microprocessor interface block.
3. Toggle the ALE input pin "High". This step enables the address bus input drivers, within the microprocessor interface block of the LIU.
4. The µP should then toggle the ALE pin "Low". This step causes the LIU to latch the contents of the address
bus into its internal circuitry. At this point, the address of the register has now been selected.
5. The µP should then place the byte or word that it intends to write into the target register, on the bi-directional data bus DATA[7:0].
6. Next, the µP should indicate that this current bus cycle is a Write operation by toggling the WR input pin
"Low". This action also enables the bi-directional data bus input drivers of the LIU.
7. After the µP toggles the Write signal "Low", the LIU will toggle the RDY output pin "Low". The LIU does this
in order to inform the µP that the data has been written into the internal register location, and that it is ready
for the next command.
NOTE: ALE can be tied “High” if this signal is not available.
The Intel Read and Write timing diagram is shown in Figure 42. The timing specifications are shown in
Table 18.
45
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
FIGURE 42. INTEL µP INTERFACE SIGNALS DURING PROGRAMMED I/O READ AND WRITE OPERATIONS
READ OPERATION
ALE = 1
WRITE OPERATION
t0
t0
ADDR[10:0]
Valid Address
Valid Address
CS
DATA[7:0]
Valid Data for Readback
Data Available to Write Into the LIU
t1
RD
t3
WR
t2
t4
RDY
TABLE 18: INTEL MICROPROCESSOR INTERFACE TIMING SPECIFICATIONS
SYMBOL
PARAMETER
MIN
MAX
UNITS
t0
Valid Address to CS Falling Edge
0
-
ns
t1
CS Falling Edge to RD Assert
30
-
ns
t2
RD Assert to RDY Assert
-
150
ns
RD Pulse Width (t2)
150
-
ns
t3
CS Falling Edge to WR Assert
30
-
ns
t4
WR Assert to RDY Assert
-
150
ns
150
-
ns
NA
NA
WR Pulse Width (t4)
46
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
5.3 MOTOROLA MODE PROGRAMMED I/O ACCESS (SYNCHRONOUS)
If the LIU is interfaced to a Motorola type µP, it should be configured to operate in the Motorola mode. Motorola
type programmed I/O Read and Write operations are described below.
Motorola Mode Read Cycle
Whenever a Motorola type µP wishes to read the contents of a register, it should do the following.
1. Place the address of the target register on the address bus input pins ADDR[10:0].
2. While the µP is placing this address value on the address bus, the address decoding circuitry should
assert the CS pin of the LIU, by toggling it "Low". This action enables further communication between the
µP and the LIU microprocessor interface block.
3. The µP should then toggle the TS pin "Low". This step causes the LIU to latch the contents of the address
bus into its internal circuitry. At this point, the address of the register has now been selected.
4. Next, the µP should indicate that this current bus cycle is a Read operation by pulling the R/W input pin
"High".
5. Toggle the WE input pin "Low". This action enables the bi-directional data bus output drivers of the LIU.
6. After the µP toggles the WE signal "Low", the LIU will toggle the TA output pin "Low". The LIU does this in
order to inform the µP that the data is available to be read by the µP, and that it is ready for the next command.
7. After the µP detects the TA signal and has read the data, it can terminate the Read Cycle by toggling the
WE input pin "High".
Motorola Mode Write Cycle
Whenever a motorola type µP wishes to write a byte or word of data into a register within the LIU, it should do
the following.
1. Place the address of the target register on the address bus input pins ADDR[10:0].
2. While the µP is placing this address value on the address bus, the address decoding circuitry should
assert the CS pin of the LIU, by toggling it "Low". This action enables further communication between the
µP and the LIU microprocessor interface block.
3. The µP should then toggle the TS pin "Low". This step causes the LIU to latch the contents of the address
bus into its internal circuitry. At this point, the address of the register has now been selected.
4. Next, the µP should indicate that this current bus cycle is a Write operation by pulling the R/W input pin
"Low".
5. Toggle the WE input pin "Low". This action enables the bi-directional data bus output drivers of the LIU.
6. After the µP toggles the WE signal "Low", the LIU will toggle the TA output pin "Low". The LIU does this in
order to inform the µP that the data has been written into the internal register location, and that it is ready
for the next command.
7. After the µP detects the TA signal and has read the data, it can terminate the Read Cycle by toggling the
WE input pin "High".
The Motorola Read and Write timing diagram is shown in Figure 43. The timing specifications are shown in
Table 19.
47
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14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
FIGURE 43. MOTOROLA µP INTERFACE SIGNALS DURING PROGRAMMED I/O READ AND WRITE OPERATIONS
READ OPERATION
WRITE OPERATION
TS
tdc
uPCLK
tcp
t0
t0
Valid Address
ADDR[10:0]
Valid Address
t3
t3
CS
Valid Data for Readback
DATA[7:0]
t1
Data Available to Write Into the LIU
t1
WE
R/W
t2
TA
t2
TABLE 19: INTEL MICROPROCESSOR INTERFACE TIMING SPECIFICATIONS
SYMBOL
PARAMETER
MIN
MAX
UNITS
t0
Valid Address to CS Falling Edge
0
-
ns
t1
CS Falling Edge to WE Assert
0
-
ns
t2
WE Assert to TA Assert
-
150
ns
150
-
ns
NA
WE Pulse Width (t2)
t3
CS Falling Edge to TS Falling Edge
0
-
tdc
µPCLK Duty Cycle
40
60
%
tcp
µPCLK Clock Period
20
-
ns
48
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REV. 1.0.0
FIGURE 44. MOTOROLA 68K µP INTERFACE SIGNALS DURING PROGRAMMED I/O READ AND WRITE OPERATIONS
MOTOROLA ASYCHRONOUS MODE
READ OPERATION
ALE_TS
WRITE OPERATION
t0
t0
Valid Address
ADDR[10:0]
Valid Address
t3
t3
CS
Valid Data for Readback
DATA[7:0]
t1
Data Available to Write Into the LIU
t1
RD_WE
WR_R/W
t2
RDY_DTACK
t2
TABLE 20: MOTOROLA 68K MICROPROCESSOR INTERFACE TIMING SPECIFICATIONS
SYMBOL
PARAMETER
MIN
MAX
UNITS
t0
Valid Address to CS Falling Edge
0
-
ns
t1
CS Falling Edge to DS (Pin RD_WE) Assert
30
-
ns
t2
DS Assert to DTACK Assert
-
150
ns
150
-
ns
0
-
ns
NA
t3
DS Pulse Width (t2)
CS Falling Edge to AS (Pin ALE_TS) Falling Edge
49
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TABLE 21: MICROPROCESSOR REGISTER ADDRESS (ADDR[7:0])
REGISTER
NUMBER
ADDRESS (HEX)
0 - 15
0x00 - 0x0F
Channel 0 Control Registers
16 - 31
0x10 - 0x1F
Channel 1 Control Registers
32 - 47
0x20 - 0x2F
Channel 2 Control Registers
48 - 63
0x30 - 0x3F
Channel 3 Control Registers
64 - 79
0x40 - 0x4F
Channel 4 Control Registers
80 - 95
0x50 - 0x5F
Channel 5 Control Registers
96 - 111
0x60 - 0x6F
Channel 6 Control Registers
112 - 127
0x70 - 0x7F
Channel 7 Control Registers
128 - 143
0x80 - 0x8F
Channel 8 Control Registers
144 - 159
0x90 - 0x9F
Channel 9 Control Registers
160 - 175
0xA0 - 0xAF
Channel 10 Control Registers
176 - 191
0xB0 - 0xBF
Channel 11 Control Registers
192 - 207
0xC0 - 0xCF
Channel 12 Control Registers
208 - 223
0xD0 - 0xDF
Channel 13 Control Registers
224 - 227
0xE0 - 0xEB
Global Control Registers Applied to All 14 Channels
228 - 243
0xEC - 0xF3
R/W Registers Reserved for Testing
244
0xF4
245 - 253
0xF5 - 0xFD
254
0xFE
Device "ID"
255
0xFF
Device "Revision ID"
FUNCTION
E1 Arbitrary Select
R/W Registers Reserved for Testing
TABLE 22: MICROPROCESSOR REGISTER CHANNEL DESCRIPTION
REG
ADDR TYPE
D7
D6
D5
D4
D3
D2
D1
D0
Channel 0 Control Registers (0x00 - 0x0F)
0
0x00
R/W
QRSS/PRBS
Reserved
RxON
EQC4
EQC3
EQC2
EQC1
EQC0
1
0x01
R/W
RxTSEL
TxTSEL
TERSEL1
TERSEL0
RxJASEL
TxJASEL
JABW
FIFOS
2
0x02
R/W
INVQRSS
TxTEST2
TxTEST1
TxTEST0
TxON
LOOP2
LOOP1
LOOP0
3
0x03
R/W
NLCDE1
NLCDE0
CODES
RxRES1
RxRES0
INSBPV
INSBER
Reserved
4
0x04
R/W
EQFLAGE
DMOIE
FLSIE
LCV/OFIE
NLCDIE
AISDIE
RLOSIE
QRPDIE
5
0x05
RO
EQFLAG
DMO
FLS
LCV/OF
NLCD
AIS
RLOS
QRPD
6
0x06
RUR
EQFLAGS
DMOIS
FLSIS
LCV/OFIS
NLCDIS
AISIS
RLOSIS
QRPDIS
50
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14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 22: MICROPROCESSOR REGISTER CHANNEL DESCRIPTION
REG
ADDR TYPE
D7
D6
D5
D4
D3
D2
D1
D0
7
0x07
RO
Reserved
FLSDET
CLOS5
CLOS4
CLOS3
CLOS2
CLOS1
CLOS0
8
0x08
R/W
Reserved
1SEG6
1SEG5
1SEG4
1SEG3
1SEG2
1SEG1
1SEG0
9
0x09
R/W
Reserved
2SEG6
2SEG5
2SEG4
2SEG3
2SEG2
2SEG1
2SEG0
10
0x0A
R/W
Reserved
3SEG6
3SEG5
3SEG4
3SEG3
3SEG2
3SEG1
3SEG0
11
0x0B
R/W
Reserved
4SEG6
4SEG5
4SEG4
4SEG3
4SEG2
4SEG1
4SEG0
12
0x0C
R/W
Reserved
5SEG6
5SEG5
5SEG4
5SEG3
5SEG2
5SEG1
5SEG0
13
0x0D
R/W
Reserved
6SEG6
6SEG5
6SEG4
6SEG3
6SEG2
6SEG1
6SEG0
14
0x0E
R/W
Reserved
7SEG6
7SEG5
7SEG4
7SEG3
7SEG2
7SEG1
7SEG0
15
0x0F
R/W
Reserved
8SEG6
8SEG5
8SEG4
8SEG3
8SEG2
8SEG1
8SEG0
Channel (1 - 13) Control Registers (0xN0 - 0xNF) See Channel 0
TABLE 23: MICROPROCESSOR REGISTER GLOBAL DESCRIPTION
REG
ADDR TYPE
D7
D6
D5
D4
D3
D2
D1
D0
Global Control Registers for All 14 Channels
224
0xE0
R/W
SR/DR
ATAOS
RCLKE
TCLKE
DATAP
Reserved
GIE
SRESET
225
0xE1
R/W
Reserved
Reserved
GAUGE1
GAUGE0
Reserved
RxMUTE
EXLOS
ICT
226
0xE2
R/W
Reserved
RxTCNTL
EQFLAG5
EQFLAG4
EQFLAG3
EQFLAG2
EQFLAG1
EQFLAG0
227
0xE3
R/W
Reserved
Reserved
Reserved
Reserved
SL1
SL0
EQG1
EQG0
228
0xE4
R/W
MCLKT1out1
MCLKT1out0
MCLKE1out1
MCLKE1out0
Reserved
Reserved
Reserved
Reserved
229
0xE5
R/W
LCV/OFLW
CNTRDEN
Reserved
Reserved
LCVCH3
LCVCH2
LCVCH1
LCVCH0
230
0xE6
R/W
Reserved
Reserved
Reserved
allRST
allUPDATE
BYTEsel
chUPDATE
chRST
231
0xE7
R/W
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
232
0xE8
RO
LCVCNT7
LCVCNT6
LCVCNT5
LCVCNT4
LCVCNT3
LCVCNT2
LCVCNT1
LCVCNT0
233
0xE9
R/W
Reserved
Reserved
ALLT1E1
TCLKCNL
CLKSEL3
CLKSEL2
CLKSEL1
CLKSEL0
234
0xEA
RUR
GCHIS7
GCHIS6
GCHIS5
GCHIS4
GCHIS3
GCHIS2
GCHIS1
GCHIS0
235
0xEB
RUR
Reserved
Reserved
GCHIS13
GCHIS12
GCHIS11
GCHIS10
GCHIS9
GCHIS8
244
0xF4
R/W
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
E1arben
R/W Registers Reserved for Testing (0xEC - 0xFD), Excluding 0xF4h
254
0xFE
RO
Device "ID"
255
0xFF
RO
Device "Revision ID"
51
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 24: MICROPROCESSOR REGISTER 0X00H BIT DESCRIPTION
CHANNEL 0-13 (0X00H-0XD0H)
BIT
NAME
D7
QRSS/
PRBS
D6
Reserved
D5
RxON
D4
D3
D2
D1
D0
EQC4
EQC3
EQC2
EQC1
EQC0
Register
Type
Default
Value
(HW reset)
R/W
0
Receiver ON/OFF
Upon power up, the receiver is powered OFF. RxON is used to
turn the receiver ON or OFF if the hardware pin RxON is pulled
"High". If the hardware pin is pulled "Low", all receivers are turned
off.
0 = Receiver is Powered Off
1 = Receiver is Powered On
R/W
0
Equalizer Control Bits
The equalizer control bits are shown in Table 25 below.
R/W
0
0
0
0
0
FUNCTION
QRSS/PRBS Select Bits
These bits are used to select between QRSS and PRBS.
0 = QRSS
1 = PRBS
This Register Bit is Not Used.
TABLE 25: EQUALIZER CONTROL AND TRANSMIT LINE BUILD OUT
EQC[4:0]
T1/E1 MODE/RECEIVE SENSITIVITY
TRANSMIT LBO
CABLE
CODING
0x00h
T1 Long Haul/36dB
0dB
100Ω TP
B8ZS
0x01h
T1 Long Haul/36dB
-7.5dB
100Ω TP
B8ZS
0x02h
T1 Long Haul/36dB
-15dB
100Ω TP
B8ZS
0x03h
T1 Long Haul/36dB
-22.5dB
100Ω TP
B8ZS
0x04h
T1 Long Haul/45dB
0dB
100Ω TP
B8ZS
0x05h
T1 Long Haul/45dB
-7.5dB
100Ω TP
B8ZS
0x06h
T1 Long Haul/45dB
-15dB
100Ω TP
B8ZS
0x07h
T1 Long Haul/45dB
-22.5dB
100Ω TP
B8ZS
0x08h
T1 Short Haul/15dB
0 to 133 feet (0.6dB)
100Ω TP
B8ZS
0x09h
T1 Short Haul/15dB
133 to 266 feet (1.2dB)
100Ω TP
B8ZS
0x0Ah
T1 Short Haul/15dB
266 to 399 feet (1.8dB)
100Ω TP
B8ZS
0x0Bh
T1 Short Haul/15dB
399 to 533 feet (2.4dB)
100Ω TP
B8ZS
0x0Ch
T1 Short Haul/15dB
533 to 655 feet (3.0dB)
100Ω TP
B8ZS
52
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REV. 1.0.0
TABLE 25: EQUALIZER CONTROL AND TRANSMIT LINE BUILD OUT
EQC[4:0]
T1/E1 MODE/RECEIVE SENSITIVITY
TRANSMIT LBO
CABLE
CODING
0x0Dh
T1 Short Haul/15dB
Arbitrary Pulse
100Ω TP
B8ZS
0x0Eh
T1 Gain Mode/29dB
0 to 133 feet (0.6dB)
100Ω TP
B8ZS
0x0Fh
T1 Gain Mode/29dB
133 to 266 feet (1.2dB)
100Ω TP
B8ZS
0x10h
T1 Gain Mode/29dB
266 to 399 feet (1.8dB)
100Ω TP
B8ZS
0x11h
T1 Gain Mode/29dB
399 to 533 feet (2.4dB)
100Ω TP
B8ZS
0x12h
T1 Gain Mode/29dB
533 to 655 feet (3.0dB)
100Ω TP
B8ZS
0x13h
T1 Gain Mode/29dB
Arbitrary Pulse
100Ω TP
B8ZS
0x14h
T1 Gain Mode/29dB
0dB
100Ω TP
B8ZS
0x15h
T1 Gain Mode/29dB
-7.5dB
100Ω TP
B8ZS
0x16h
T1 Gain Mode/29dB
-15dB
100Ω TP
B8ZS
0x17h
T1 Gain Mode/29dB
-22.5dB
100Ω TP
B8ZS
0x18h
E1 Long Haul/36dB
ITU G.703
75Ω Coax
HDB3
0x19h
E1 Long Haul/36dB
ITU G.703
120Ω TP
HDB3
0x1Ah
E1 Long Haul/45dB
ITU G.703
75Ω Coax
HDB3
0x1Bh
E1 Long Haul/45dB
ITU G.703
120Ω TP
HDB3
0x1Ch
E1 Short Haul/15dB
ITU G.703
75Ω Coax
HDB3
0x1Dh
E1 Short Haul/15dB
ITU G.703
120Ω TP
HDB3
0x1Eh
E1 Gain Mode/29dB
ITU G.703
75Ω Coax
HDB3
0x1Fh
E1 Gain Mode/29dB
ITU G.703
120Ω TP
HDB3
53
XRT83L314
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REV. 1.0.0
TABLE 26: MICROPROCESSOR REGISTER 0X01H BIT DESCRIPTION
CHANNEL 0-13 (0X01H-0XD1H)
Register
Type
Default
Value
(HW reset)
Receive Termination Select
Upon power up, the receiver is in "High" impedance. RxTSEL is
used to switch between the internal termination and "High" impedance.
0 = "High" Impedance
1 = Internal Termination
R/W
0
TxTSEL
Transmit Termination Select
Upon power up, the transmitter is in "High" impedance. TxTSEL is
used to switch between the internal termination and "High" impedance.
0 = "High" Impedance
1 = Internal Termination
R/W
0
D5
D4
TERSEL1
TERSEL0
Receive Line Impedance Select
TERSEL[1:0] are used to select the line impedance for T1/J1/E1.
00 = 100Ω
01 = 110Ω
10 = 75Ω
11 = 120Ω
R/W
0
0
D3
RxJASEL
Receive Jitter Attenuator Select
RxJASEL is used to enable the receiver jitter attenuator.
default, RxJASEL is disabled.
0 = Disabled
1 = Enabled
R/W
0
BIT
NAME
FUNCTION
D7
RxTSEL
D6
By
D2
TxJASEL
Transmit Jitter Attenuator Select
TxJASEL is used to enable the transmitter jitter attenuator. By
default, TxJASEL is disabled.
0 = Disabled
1 = Enabled
R/W
0
D1
JABW
Jitter Bandwidth (E1 Mode Only, T1 is permanently set to 3Hz)
The jitter bandwidth is a global setting that is applied to both the
receiver and transmitter jitter attenuator.
0 = 10Hz
1 = 1.5Hz
R/W
0
D0
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 blocks). The delay of the
FIFO is equal to ½ the FIFO depth. This is a global setting that is
applied to both the receiver and transmitter FIFO.
0 = 32-Bit
1 = 64-Bit
R/W
0
54
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14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 27: MICROPROCESSOR REGISTER 0X02H BIT DESCRIPTION
CHANNEL 0-13 (0X02H-0XD2H)
Register
Type
Default
Value
(HW reset)
QRSS inversion
INVQRSS is used to invert the transmit QRSS pattern set by the
TxTEST[2:0] bits. By default, INVQRSS is disabled and the QRSS
will be transmitted with normal polarity.
0 = Disabled
1 = Enabled
R/W
0
TxTEST2
TxTEST1
TxTEST0
Test Code Pattern
TxTEST[2:0] are used to select a diagnostic test pattern to the line
(transmit outputs).
0XX = No Pattern
100 = Tx QRSS
101 = Tx TAOS
110 = Tx TLUC
111 = Tx TLDC
R/W
0
0
0
D3
TxOn
Transmit ON/OFF
Upon power up, the transmitters are powered off. This bit is used
to turn the transmitter for this channel On or Off if the TxON pin is
pulled "High". If the TxON pin is pulled "Low", all 14 transmitters
are powered off.
0 = Transmitter is Powered OFF
1 = Transmitter is Powered ON
R/W
0
D2
D1
D0
LOOP2
LOOP1
LOOP0
Loopback Diagnostic Select
LOOP[2:0] are used to select the loopback mode.
0XX = No Loopback
100 = Dual Loopback
101 = Analog Loopback
110 = Remote Loopback
111 = Digital Loopback
R/W
0
0
0
BIT
NAME
FUNCTION
D7
INVQRSS
D6
D5
D4
55
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REV. 1.0.0
TABLE 28: MICROPROCESSOR REGISTER 0X03H BIT DESCRIPTION
CHANNEL 0-13 (0X03H-0XD3H)
Register
Type
Default
Value
(HW reset)
Network Loop Code Detection Enable
NLCDE[1:0] are used to select the loop code detection.
00 = Disabled
01 = Detect Loop Up Code
10 = Detect Loop Down Code
11 = Automatic Loop Code Detection
R/W
0
0
CODES
Encoding/Decoding Select (Single Rail Mode Only)
0 = HDB3 (E1), B8ZS (T1)
1 = AMI Coding
R/W
0
D4
D3
RxRES1
RxRES0
Receive External Fixed Resistor
RxRES[1:0] are used to select the value for a high precision external resistor to improve return loss.
00 = None
01 = 240Ω
10 = 210Ω
11 = 150Ω
R/W
0
0
D2
INSBPV
Insert Bipolar Violation
When this bit transitions from a "0" to a "1", a bipolar violation will
be inserted in the transmitted QRSS/PRBS pattern. The state of
this bit will be sampled on the rising edge of TCLK. To ensure
proper operation, it is recommended to write a "0" to this bit before
writing a "1".
R/W
0
D1
INSBER
Insert Bit Error
When this bit transitions from a "0" to a "1", a bit error will be
inserted in the transmitted QRSS/PRBS pattern. The state of this
bit will be sampled on the rising edge of TCLK. To ensure proper
operation, it is recommended to write a "0" to this bit before writing
a "1".
R/W
0
D0
Reserved
This Register Bit is Not Used.
BIT
NAME
D7
D6
NLCDE1
NLCDE0
D5
FUNCTION
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TABLE 29: MICROPROCESSOR REGISTER 0X04H BIT DESCRIPTION
CHANNEL 0-13 (0X04H-0XD4H)
BIT
D7
NAME
FUNCTION
EQFLAGE Equalizer Attenuation Flag Enable
0 = Masks the EQFLAG function
1 = Enables Interrupt Generation
Register
Type
Default
Value
(HW reset)
R/W
0
D6
DMOIE
Digital Monitor Output Interrupt Enable
0 = Masks the DMO function
1 = Enables Interrupt Generation
R/W
0
D5
FLSIE
FIFO Limit Status Interrupt Enable
0 = Masks the FLS function
1 = Enables Interrupt Generation
R/W
0
D4
LCV/OFIE
Line Code Violation / Counter Overflow Interrupt Enable
0 = Masks the LCV/OF function
1 = Enables Interrupt Generation
R/W
0
D3
NLCDIE
Network Loop Code Detection Interrupt Enable
0 = Masks the NLCD function
1 = Enables Interrupt Generation
R/W
0
D2
AISIE
Alarm Indication Signal Interrupt Enable
0 = Masks the AIS function
1 = Enables Interrupt Generation
R/W
0
D1
RLOSIE
Receiver Loss of Signal Interrupt Enable
0 = Masks the RLOS function
1 = Enables Interrupt Generation
R/W
0
D0
QRPDIE
Quasi Random Signal Source Interrupt Enable
0 = Masks the QRPD function
1 = Enables Interrupt Generation
R/W
0
57
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REV. 1.0.0
NOTE: The GIE bit in the global register 0xE0h must be set to "1" in addition to the individual register bits to enable the
interrupt pin.
TABLE 30: MICROPROCESSOR REGISTER 0X05H BIT DESCRIPTION
CHANNEL 0-13 (0X05H-0XD5H)
Register
Type
Default
Value
(HW reset)
Equalizer Attenuation Flag
The equalizer attenuation flag is always active regardless if the
interrupt generation is disabled. This bit indicates the EQFLAG
activity. An interrupt will not occur unless the EQFLAGE is set to
"1" in the channel register 0x04h and GIE is set to "1" in the global
register 0xE0h.
0 = No Alarm
1 = Equalizer Attenuation Flag is Set
RO
0
DMO
Digital Monitor Output
The digital 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
RO
0
D5
FLS
FIFO Limit Status
The FIFO limit status is always active regardless if the interrupt
generation is disabled. This bit indicates whether the RD/WR
pointers are within 3-Bits. An interrupt will not occur unless the
FLSIE is set to "1" in the channel register 0x04h and GIE is set to
"1" in the global register 0xE0h.
0 = No Alarm
1 = RD/WR FIFO pointers are within ±3-Bits
RO
0
D4
LCV/OF
Line Code Violation / Counter Overflow
This bit serves a dual purpose. By default, this bit monitors the line
code violation activity. However, if bit 7 in register 0xE5h is set to a
"1", this bit monitors the overflow status of the internal LCV
counter. An interrupt will not occur unless the LCV/OFIE is set to
"1" in the channel register 0x04h and GIE is set to "1" in the global
register 0xE0h.
0 = No Alarm
1 = A line code violation, bipolar violation, or excessive zeros has
occurred
RO
0
D3
NLCD
Network Loop Code Detection
The network loop code detection is always active regardless if the
interrupt generation is disabled. This bit indicates the NLCD activity. An interrupt will not occur unless the NLCDIE is set to "1" in the
channel register 0x04h and GIE is set to "1" in the global register
0xE0h.
0 = No Alarm
1 = Network loop code detected according to the mode selected in
channel register 0x03h
RO
0
BIT
NAME
FUNCTION
D7
EQFLAG
D6
58
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NOTE: The GIE bit in the global register 0xE0h must be set to "1" in addition to the individual register bits to enable the
interrupt pin.
TABLE 30: MICROPROCESSOR REGISTER 0X05H BIT DESCRIPTION
CHANNEL 0-13 (0X05H-0XD5H)
Register
Type
Default
Value
(HW reset)
Alarm Indication Signal
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.
0 = No Alarm
1 = An all ones signal is detected
RO
0
RLOS
Receiver Loss of Signal
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.
0 = No Alarm
1 = An RLOS condition is present
RO
0
QRPD
Quasi Random Pattern Detection
The quasi random pattern detection is always active regardless if
the interrupt generation is disabled. This bit indicates that a QRPD
has been detected. An interrupt will not occur unless the QRPDIE
is set to "1" in the channel register 0x04h and GIE is set to "1" in
the global register 0xE0h.
0 = No Alarm
1 = A QRP is detected
RO
0
Register
Type
Default
Value
(HW reset)
RUR
0
BIT
NAME
FUNCTION
D2
AISD
D1
D0
TABLE 31: MICROPROCESSOR REGISTER 0X06H BIT DESCRIPTION
CHANNEL 0-13 (0X06H-0XD6H)
BIT
D7
NAME
FUNCTION
EQFLAGS Equalizer Attenuation Flag Status
0 = No change
1 = Change in status occurred
D6
DMOIS
Digital Monitor Output Status
0 = No change
1 = Change in status occurred
RUR
0
D5
FLSIS
FIFO Limit Status
0 = No change
1 = Change in status occurred
RUR
0
59
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TABLE 31: MICROPROCESSOR REGISTER 0X06H BIT DESCRIPTION
CHANNEL 0-13 (0X06H-0XD6H)
Register
Type
Default
Value
(HW reset)
Line Code Violation / Counter Overflow Status
0 = No change
1 = Change in status occurred
RUR
0
NLCDIS
Network Loop Code Detection Status
0 = No change
1 = Change in status occurred
RUR
0
D2
AISDIS
Alarm Indication Signal Status
0 = No change
1 = Change in status occurred
RUR
0
D1
RLOSIS
Receiver Loss of Signal Status
0 = No change
1 = Change in status occurred
RUR
0
D0
QRPDIS
Quasi Random Pattern Detection Status
0 = No change
1 = Change in status occurred
RUR
0
BIT
NAME
D4
LCV/OFIS
D3
FUNCTION
NOTE: Any change in status will generate an interrupt (if enabled in channel register 0x04h and GIE is set to "1" in the
global register 0xE0h). The status registers are reset upon read (RUR).
TABLE 32: MICROPROCESSOR REGISTER 0X07H BIT DESCRIPTION
CHANNEL 0-13 (0X07H-0XD7H)
Register
Type
Default
Value
(HW reset)
This Register Bit is Not Used
R/W
0
FLSDET
FIFO LIMIT STATUS DETECT
The FLSDET is used to determine whether the receiver or transmitter FIFO has reached its limit status. If both FIFOs reach their
limit capacity, this bit will be set to "1".
0 = Receive JA
1 = Transmit JA
RO
0
CLOS5
CLOS4
CLOS3
CLOS2
CLOS1
CLOS0
Cable Loss Indication
This 6-Bit binary word indicates the cable attenuation on the
receiver inputs RTIP/RRING within ±1dB with Bit 5 being the MSB.
RO
0
BIT
NAME
D7
Reserved
D6
D5
D4
D3
D2
D1
D0
FUNCTION
60
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TABLE 33: MICROPROCESSOR REGISTER 0X08H BIT DESCRIPTION
CHANNEL 0-13 (0X08H-0XD8H)
BIT
NAME
D7
Reserved
D6
D5
D4
D3
D2
D1
D0
1SEG6
1SEG5
1SEG4
1SEG3
1SEG2
1SEG1
1SEG0
FUNCTION
This Register Bit is Not Used
Arbitrary Pulse Generation
The transmit output pulse is divided into 8 individual segments.
This register is used to program the first segment which corresponds to the overshoot of the pulse amplitude. There are four
segments for the top portion of the pulse and four segments for the
bottom portion of the pulse. Segment number 5 corresponds to
the undershoot of the pulse. The MSB of each segment is the sign
bit.
Bit 6 = 0 = Negative Direction
Bit 6 = 1 = Positive Direction
Register
Type
Default
Value
(HW reset)
X
0
R/W
0
0
0
0
0
0
0
Register
Type
Default
Value
(HW reset)
X
0
TABLE 34: MICROPROCESSOR REGISTER 0X09H BIT DESCRIPTION
CHANNEL 0-13 (0X09H-0XD9H)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
D[6:0]
2SEG[6:0]
Segment Number Two, Same Description as Register 0x08h
R/W
TABLE 35: MICROPROCESSOR REGISTER 0X0AH BIT DESCRIPTION
CHANNEL 0-13 (0X0AH-0XDAH)
BIT
NAME
D7
Reserved
This Register Bit is Not Used
D[6:0]
3SEG[6:0]
Segment Number Three, Same Description as Register 0x08h
FUNCTION
61
Register
Type
Default
Value
(HW reset)
X
0
R/W
XRT83L314
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REV. 1.0.0
TABLE 36: MICROPROCESSOR REGISTER 0X0BH BIT DESCRIPTION
CHANNEL 0-13 (0X0BH-0XDBH)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
D[6:0]
4SEG[6:0]
Segment Number Four, Same Description as Register 0x08h
Register
Type
Default
Value
(HW reset)
X
0
R/W
TABLE 37: MICROPROCESSOR REGISTER 0X0CH BIT DESCRIPTION
CHANNEL 0-13 (0X0CH-0XDCH)
BIT
NAME
D7
Reserved
This Register Bit is Not Used
D[6:0]
5SEG[6:0]
Segment Number Five, Same Description as Register 0x08h
FUNCTION
Register
Type
Default
Value
(HW reset)
X
0
R/W
TABLE 38: MICROPROCESSOR REGISTER 0X0DH BIT DESCRIPTION
CHANNEL 0-13 (0X0DH-0XDDH)
BIT
NAME
D7
Reserved
This Register Bit is Not Used
D[6:0]
6SEG[6:0]
Segment Number Six, Same Description as Register 0x08h
FUNCTION
Register
Type
Default
Value
(HW reset)
X
0
R/W
TABLE 39: MICROPROCESSOR REGISTER 0X0EH BIT DESCRIPTION
CHANNEL 0-13 (0X0EH-0XDEH)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
D[6:0]
7SEG[6:0]
Segment Number Seven, Same Description as Register 0x08h
62
Register
Type
Default
Value
(HW reset)
X
0
R/W
XRT83L314
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REV. 1.0.0
TABLE 40: MICROPROCESSOR REGISTER 0X0FH BIT DESCRIPTION
CHANNEL 0-13 (0X0FH-0XDFH)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
D[6:0]
8SEG[6:0]
Segment Number Eight, Same Description as Register 0x08h
Register
Type
Default
Value
(HW reset)
X
0
R/W
TABLE 41: MICROPROCESSOR REGISTER 0XE0H BIT DESCRIPTION
GLOBAL REGISTER (0XE0H)
Register
Type
Default
Value
(HW reset)
Single Rail/Dual Rail Mode
This bit sets the LIU to receive and transmit digital data in a single
rail or a dual rail format.
0 = Dual Rail Mode
1 = Single Rail Mode
R/W
0
ATAOS
Automatic Transmit All Ones
If ATAOS is selected, an all ones pattern will be transmitted on any
channel that experiences an RLOS condition. If an RLOS condition does not occur, TAOS will remain inactive.
0 = Disabled
1 = Enabled
R/W
0
D5
RCLKE
Receive 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
D4
TCLKE
Transmit 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
D3
DATAP
Data Polarity
0 = Transmit input and receive output data is active "High"
1 = Transmit input and receive output data is active "Low"
R/W
0
D2
Reserved
This Register Bit is Not Used
R/W
0
BIT
NAME
FUNCTION
D7
SR/DR
D6
63
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REV. 1.0.0
TABLE 41: MICROPROCESSOR REGISTER 0XE0H BIT DESCRIPTION
GLOBAL REGISTER (0XE0H)
Register
Type
Default
Value
(HW reset)
Global Interrupt Enable
The global interrupt enable is used to enable/disable all interrupt
activity for all 14 channels. This bit must be set "High" for the interrupt pin to operate.
0 = Disable all interrupt generation
1 = Enable interrupt generation to the individual channel registers
R/W
0
Software Reset
Writing a "1" to this bit for more than 10µS initiates a device reset
for all internal circuits except the microprocessor register bits. To
reset the registers to their default setting, use the Hardware Reset
pin (See the pin description for more details).
R/W
0
Register
Type
Default
Value
(HW reset)
BIT
NAME
FUNCTION
D1
GIE
D0
SRESET
TABLE 42: MICROPROCESSOR REGISTER 0XE1H BIT DESCRIPTION
GLOBAL REGISTER (0XE1H)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
R/W
0
D6
Reserved
This Register Bit is Not Used
R/W
0
D5
D4
GAUGE1
GAUGE0
Wire Gauge Select
00 = 22 and 24 gauge
01 = 22 gauge
10 = 24 gauge
11 = 26 gauge
R/W
0
0
D3
Reserved
This Register Bit is Not Used
R/W
0
D2
RxMUTE
Receiver Output Mute Enable
If RxMUTE is selected, RPOS/RNEG will be pulled "Low" for any
channel that experiences an RLOS condition. If an RLOS condition does not occur, RxMUTE will remain inactive.
0 = Disabled
1 = Enabled
R/W
0
64
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GLOBAL REGISTER (0XE1H)
Register
Type
Default
Value
(HW reset)
Extended Loss of Zeros
The number of zeros required to declare a Digital Loss of Signal is
extended to 4,096.
0 = Normal Operation
1 = Enables the EXLOS function
R/W
0
In Circuit Testing
0 = Normal Operation
1 = Sets all output pins to "High" impedance for in circuit testing
R/W
0
Register
Type
Default
Value
(HW reset)
BIT
NAME
FUNCTION
D1
EXLOS
D0
ICT
TABLE 43: MICROPROCESSOR REGISTER 0XE2H BIT DESCRIPTION
GLOBAL REGISTER (0XE2H)
BIT
NAME
D7
Reserved
This Register Bit is Not Used
R/W
0
D6
RxTCNTL
Receive Termination Select Control
This bit sets the LIU to control the RxTSEL function with either the
individual channel register bit or the global hardware pin.
0 = Control of the receive termination is set to the register bits
1 = Control of the receive termination is set to the hardware pin
R/W
0
D5
D4
D3
D2
D1
D0
EQFLAG5
EQFLAG4
EQFLAG3
EQFLAG2
EQFLAG1
EQFLAG0
Equalizer Attenuation Flag
EQFLAG[5:0] is used to generate an interrupt condition for an
RLOS other than the default setting described in the datasheet. A
desired value can be programmed into this register. If EQFLAGE
is enabled in register 0x04h and if this 6-Bit binary word is equal to
the 6-Bit cable loss indicator, an interrupt will be generated.
R/W
0
0
0
0
0
0
Register
Type
Default
Value
(HW reset)
FUNCTION
TABLE 44: MICROPROCESSOR REGISTER 0XE3H BIT DESCRIPTION
GLOBAL REGISTER (0XE3H)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
R/W
0
D6
Reserved
This Register Bit is Not Used
R/W
0
D5
Reserved
This Register Bit is Not Used
R/W
0
D4
Reserved
This Register Bit is Not Used
R/W
0
65
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GLOBAL REGISTER (0XE3H)
BIT
NAME
D3
D2
SL1
SL0
D1
D0
EQG1
EQG0
Register
Type
Default
Value
(HW reset)
Slicer Level Select
00 = 50%
01 = 45%
10 = 55%
11 = 68%
R/W
0
0
Equalizer Gain Control
00 = Normal
01 = Reduce Gain by 1dB
10 = Reduce Gain by 3dB
11 = Normal
R/W
0
Register
Type
Default
Value
(HW reset)
FUNCTION
TABLE 45: MICROPROCESSOR REGISTER 0XE4H BIT DESCRIPTION
GLOBAL REGISTER (0XE4H)
BIT
NAME
FUNCTION
D7
D6
MclkT1out1 MCLKT1OUT Select
MclkT1out0 MclkT1out[1:0] is used to program the MCLKT1out pin. By default,
the output clock is 1.544MHz.
00 = 1.544MHz
01 = 3.088MHz
10 = 6.176MHz
11 = 12.352MHz
R/W
0
0
D5
D4
MclkE1out1 MCLKE1OUT Select
MclkE1out0 MclkE1out[1:0] is used to program the MCLKE1out pin.
default, the output clock is 2.048MHz.
00 = 2.048MHz
01 = 4.096MHz
10 = 8.192MHz
11 = 16.384MHz
R/W
0
0
By
D3
Reserved
This Register Bit is Not Used
R/W
0
D2
Reserved
This Register Bit is Not Used
R/W
0
D1
Reserved
This Register Bit is Not Used
R/W
0
D0
Reserved
This Register Bit is Not Used
R/W
0
66
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REV. 1.0.0
TABLE 46: MICROPROCESSOR REGISTER 0XE5H BIT DESCRIPTION
GLOBAL REGISTER (0XE5H)
BIT
NAME
FUNCTION
Register
Type
Default
Value
(HW reset)
D7
LCV/OFLW Line Code Violation / Counter Overflow Monitor Select
This bit is used to select the monitoring activity between the LCV
and the counter overflow status. When the 16-bit LCV counter saturates, the counter overflow condition is activated. By default, the
LCV activity is monitored by bit D4 in register 0x05h.
0 = Monitoring LCV
1 = Monitoring the counter overflow status
R/W
0
D6
CNTRDEN Line Code Violation Counter Read Enable
This bit enables the 16-bit LCV counter contents to be read from
bits D[7:0] in register 0xE8h. If a counter reaches full scale, it saturates and remains at FFFFh until a reset is initiated in register
0xE6h. By default the LCV counter readback function is disabled.
0 = Disabled
1 = Enables the 16-bit LCV Counters for Readback
R/W
0
D5
Reserved
This Register Bit is Not Used
R/W
0
D4
Reserved
This Register Bit is Not Used
R/W
0
D3
D2
D1
D0
LCVCH3
LCVCH2
LCVCH1
LCVCH0
Line Code Violation Counter Select
These bits are used to select which channel is to be addressed for
reading the contents in register 0xE8h. It is also used to address
the counter for a given channel when performing an update or
reset on a per channel basis. By default, Channel 0 is selected.
0000 = None
0001 = Channel 0
0010 = Channel 1
0011 = Channel 2
0100 = Channel 3
0101 = Channel 4
0110 = Channel 5
0111 = Channel 6
1000 = Channel 7
1001 = Channel 8
1010 = Channel 9
1011 = Channel 10
1100 = Channel 11
1101 = Channel 12
1110 = Channel 13
R/W
0
67
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REV. 1.0.0
TABLE 47: MICROPROCESSOR REGISTER 0XE6H BIT DESCRIPTION
GLOBAL REGISTER (0XE6H)
Register
Type
Default
Value
(HW reset)
This Register Bit is Not Used
R/W
0
Reserved
This Register Bit is Not Used
R/W
0
D5
Reserved
This Register Bit is Not Used
R/W
0
D4
allRST
LCV Counter Reset for All Channels
This bit is used to reset all internal LCV counters to their default
state 0000h. This bit must be set to "1" for 1µS.
0 = Normal Operation
1 = Resets All Counters
R/W
0
allUPDATE LCV Counter Update for All Channels
This bit is used to latch the contents of all 14 counters into holding
registers so that the value of each counter can be read. The channel is addressed by using bits D[3:0] in register 0xE5h.
0 = Normal Operation
1 = Updates All Channels
R/W
0
LCV Counter Byte Select
This bit is used to select the MSB or LSB for Reading the contents
of the LCV counter for a given channel. The channel is addressed
by using bits D[3:0] in register 0xE5h. By default, the LSB byte is
selected.
0 = Low Byte
1 = High Byte
R/W
0
chUPDATE LCV Counter Update Per Channel
This bit is used to latch the contents of the counter for a given
channel into a holding register so that the value of the counter can
be read. The channel is addressed by using bits D[3:0] in register
0xE5h.
0 = Normal Operation
1 = Updates the Selected Channel
R/W
0
R/W
0
BIT
NAME
D7
Reserved
D6
D3
D2
D1
D0
BYTEsel
chRST
FUNCTION
LCV Counter Reset Per Channel
This bit is used to reset the LCV counter of a given channel to its
default state 0000h. The channel is addressed by using bits D[3:0]
in register 0xE5h. This bit must be set to "1" for 1µS.
0 = Normal Operation
1 = Resets the Selected Channel
68
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REV. 1.0.0
TABLE 48: MICROPROCESSOR REGISTER 0XE7H BIT DESCRIPTION
GLOBAL REGISTER (0XE7H)
Register
Type
Default
Value
(HW reset)
This Register Bit is Not Used
R/W
0
Reserved
This Register Bit is Not Used
R/W
0
D5
Reserved
This Register Bit is Not Used
R/W
0
D4
Reserved
This Register Bit is Not Used
R/W
0
D3
Reserved
This Register Bit is Not Used
R/W
0
D2
Reserved
This Register Bit is Not Used
R/W
0
D1
Reserved
This Register Bit is Not Used
R/W
0
D0
Reserved
This Register Bit is Not Used
R/W
0
Register
Type
Default
Value
(HW reset)
R/W
0
0
0
0
0
0
0
0
BIT
NAME
D7
Reserved
D6
FUNCTION
TABLE 49: MICROPROCESSOR REGISTER 0XE8H BIT DESCRIPTION
GLOBAL REGISTER (0XE8H)
BIT
NAME
FUNCTION
D7
D6
D5
D4
D3
D2
D1
D0
LCVCNT7
LCVCNT6
LCVCNT5
LCVCNT4
LCVCNT3
LCVCNT2
LCVCNT1
LCVCNT0
Line Code Violation Byte Contents
These bits contain the LCV counter contents of the Byte selected
by bit D2 in register 0xE6h for a given channel. The channel is
addressed by using bits D[3:0] in register 0xE5h. By default the
contents contain the LSB for Channel 0.
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
CLOCK SELECT REGISTER
The input clock source is used to generate all the necessary clock references internally to the LIU. The
microprocessor timing is derived from a PLL output which is chosen by programming the Clock Select Bits in
register 0xE9h. Therefore, if the clock selection bits are being programmed, the frequency of the PLL output
will be adjusted accordingly. During this adjustment, it is important to "Not" write to any other bit location within
the same register while selecting the input/output clock frequency. For best results, register 0xE9h can be
broken down into two sub-registers with the MSB being bits D[7:4] and the LSB being bits D[3:0] as shown in
Figure 45. Note: Bits D[7:6] are reserved.
FIGURE 45. REGISTER 0XE9H SUB REGISTERS
MSB
D7
D6
D5
LSB
D4
D3
ALLT1/E1, CLKCNTL
D2
D1
D0
Clock Selection Bits
Programming Examples:
Example 1: Changing bits D[7:4]
If bits D[7:4] are the only values within the register that will change in a WRITE process, the microprocessor
only needs to initiate ONE write operation.
Example 2: Changing bits D[3:0]
If bits D[3:0] are the only values within the register that will change in a WRITE process, the microprocessor
only needs to initiate ONE write operation.
Example 3: Changing bits within the MSB and LSB
In this scenario, one must initiate TWO write operations such that the MSB and LSB do not change within ONE
write cycle. It is recommended that the MSB and LSB be treated as two independent sub-registers. One can
either change the clock selection (LSB) and then change bits D[5:4] (MSB) on the SECOND write, or viceversa. No order or sequence is necessary.
TABLE 50: MICROPROCESSOR REGISTER 0XE9H BIT DESCRIPTION
GLOBAL REGISTER (0XE9H)
BIT
NAME
D7
Reserved
D6
Reserved
Register
Type
Default
Value
(HW reset)
This Register Bit is Not Used
R/W
0
This Register Bit is Not Used
R/W
0
FUNCTION
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
GLOBAL REGISTER (0XE9H)
Register
Type
Default
Value
(HW reset)
T1/E1 Control
This bit is used to reduce system noise and power consumption. If
the ALL T1/E1 mode is enabled, all output clock references
(excluding the 8kHzout in E1 mode only) are internally shut off. By
default, the ALL T1/E1 mode is enabled.
0 = Enabled (reduce clock switching and power consumption)
1 = Disabled (all clock references are available)
R/W
0
TCLKCNL
Transmit Clock Control
This bit is used to select the transmit output activity at TTIP/TRING
when TCLK is either pulled "Low", pulled "High", or missing.
0 = Transmit All Zeros
1 = TAOS (Transmit All Ones)
R/W
0
CLKSEL3
CLKSEL2
CLKSEL1
CLKSEL0
Clock Input Select
CLKSEL[3:0] is used to select the input clock source used as the
internal timing reference.
0000 = 2.048 MHz
0001 = 1.544 MHz
0010 = 8 kHz
0011 = 16 kHz
0100 = 56 kHz
0101 = 64 kHz
0110 = 128 kHz
0111 = 256 kHz
1000 = 4.096 Mhz
1001 = 3.088 Mhz
1010 = 8.192 Mhz
1011 = 6.176 Mhz
1100 = 16.384 Mhz
1101 = 12.352 Mhz
1110 = 2.048 Mhz
1111 = 1.544 Mhz
R/W
0
0
0
0
BIT
NAME
FUNCTION
D5
ALLT1/E1
D4
D3
D2
D1
D0
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 51: MICROPROCESSOR REGISTER 0XEAH BIT DESCRIPTION
GLOBAL REGISTER (0XEAH)
Register
Type
Default
Value
(HW reset)
Global Channel Interrupt Status for Channel 7
0 = No interrupt activity from channel 7
1 = Interrupt was generated from channel 7
RUR
0
GCHIS6
Global Channel Interrupt Status for Channel 6
0 = No interrupt activity from channel 6
1 = Interrupt was generated from channel 6
RUR
0
D5
GCHIS5
Global Channel Interrupt Status for Channel 5
0 = No interrupt activity from channel 5
1 = Interrupt was generated from channel 5
RUR
0
D4
GCHIS4
Global Channel Interrupt Status for Channel 4
0 = No interrupt activity from channel 4
1 = Interrupt was generated from channel 4
RUR
0
D3
GCHIS3
Global Channel Interrupt Status for Channel 3
0 = No interrupt activity from channel 3
1 = Interrupt was generated from channel 3
RUR
0
D2
GCHIS2
Global Channel Interrupt Status for Channel 2
0 = No interrupt activity from channel 2
1 = Interrupt was generated from channel 2
RUR
0
D1
GCHIS1
Global Channel Interrupt Status for Channel 1
0 = No interrupt activity from channel 1
1 = Interrupt was generated from channel 1
RUR
0
D0
GCHIS0
Global Channel Interrupt Status for Channel 0
0 = No interrupt activity from channel 0
1 = Interrupt was generated from channel 0
RUR
0
Register
Type
Default
Value
(HW reset)
BIT
NAME
D7
GCHIS7
D6
FUNCTION
TABLE 52: MICROPROCESSOR REGISTER 0XEBH BIT DESCRIPTION
GLOBAL REGISTER (0XEBH)
BIT
NAME
FUNCTION
D7
Reserved
This Register Bit is Not Used
RUR
0
D6
Reserved
This Register Bit is Not Used
RUR
0
D5
GCHIS13
Global Channel Interrupt Status for Channel 13
0 = No interrupt activity from channel 13
1 = Interrupt was generated from channel 13
RUR
0
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
GLOBAL REGISTER (0XEBH)
Register
Type
Default
Value
(HW reset)
Global Channel Interrupt Status for Channel 12
0 = No interrupt activity from channel 12
1 = Interrupt was generated from channel 12
RUR
0
GCHIS11
Global Channel Interrupt Status for Channel 11
0 = No interrupt activity from channel 11
1 = Interrupt was generated from channel 11
RUR
0
D2
GCHIS10
Global Channel Interrupt Status for Channel 10
0 = No interrupt activity from channel 10
1 = Interrupt was generated from channel 10
RUR
0
D1
GCHIS9
Global Channel Interrupt Status for Channel 9
0 = No interrupt activity from channel 9
1 = Interrupt was generated from channel 9
RUR
0
D0
GCHIS8
Global Channel Interrupt Status for Channel 8
0 = No interrupt activity from channel 8
1 = Interrupt was generated from channel 8
RUR
0
Register
Type
Default
Value
(HW reset)
R/W
0
BIT
NAME
D4
GCHIS12
D3
FUNCTION
TABLE 53: E1 ARBITRARY SELECT
E1 ARBITRARY SELECT REGISTER (0XF4H)
BIT
NAME
D[7:1]
Reserved
D0
E1arben
FUNCTION
E1 Arbitrary Pulse Enable
This bit is used to enable the Arbitrary Pulse Generators for shaping the transmit pulse shape when E1 mode is selected. If this bit
is set to "1", all 14 channels will be configured for the Arbitrary
Mode. However, each channel is individually controlled by programming the channel registers 0xn8 through 0xnF, where n is the
number of the channel.
"0" = Disabled (Normal E1 Pulse Shape ITU G.703)
"1" = Arbitrary Pulse Enabled
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 54: MICROPROCESSOR REGISTER 0XFEH BIT DESCRIPTION
DEVICE "ID" REGISTER (0XFEH)
BIT
D7
D6
D5
D4
D3
D2
D1
D0
NAME
FUNCTION
Device "ID" The device "ID" of the XRT83L314 long haul LIU is 0xFFh. Along
with the revision "ID", the device "ID" is used to enable software to
identify the silicon adding flexibility for system control and debug.
Register
Type
Default
Value
(HW reset)
RO
1
1
1
1
1
1
1
1
Register
Type
Default
Value
(HW reset)
RO
0
0
0
0
0
0
0
1
TABLE 55: MICROPROCESSOR REGISTER 0XFFH BIT DESCRIPTION
REVISION "ID" REGISTER (0XFFH)
BIT
NAME
FUNCTION
D7
D6
D5
D4
D3
D2
D1
D0
Revision
"ID"
The revision "ID" of the XRT83L314 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 will be 0x01h.
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
ELECTRICAL CHARACTERISTICS
TABLE 56: 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 57: 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
V OH
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 58: AC ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
MCLKin Clock Duty Cycle
40
-
60
%
MCLKin Clock Tolerance
-
±50
-
ppm
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XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 59: POWER CONSUMPTION
VDD=3.3V ±5%, TA=25°C, INTERNAL IMPEDANCE, UNLESS OTHERWISE SPECIFIED
MODE
SUPPLY
VOLTAGE
IMPEDANCE
RECEIVER
TRANSMITTER
TYP
MAX
UNIT
TEST
CONDITION
E1
3.3V
75Ω
1:1
1:2
2.80
3.29
W
100% ones
E1
3.3V
120Ω
1:1
1:2
2.52
2.96
W
100% ones
T1
3.3V
100Ω
1:1
1:2
2.81
3.31
W
100% ones
-
3.3V
-
1:1
1:2
620
730
mW
All Transmitters
Turned Off
TABLE 60: E1 RECEIVER ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
MIN
TYP
MAX
Number of consecutive zeros
before RLOS is declared
10
175
255
Input signal level at RLOS
15
20
UNIT
TEST CONDITION
Receiver Loss of Signal
RLOS clear
Receiver Sensitivity (short haul
with cable loss)
12.5
11
-
-
dB
Cable attenuation @ 1024kHz
dB
ITU-G.775, ETSI 300 233
dB
With nominal pulse amplitude of
3.0V for 120Ω and 2.37V for
75Ω with -18dB interference
signal added.
dB
With nominal pulse amplitude of
3.0V for 120Ω and 2.37V for
75Ω with -18dB interference
signal added.
Receiver Sensitivity
(Long haul with cable loss)
Nominal
Extended
0
0
Input Impedance
-
13
-
kΩ
37
0.2
-
-
UIp-p
-
36
-
-0.5
kHz
dB
Input Jitter Tolerance
1Hz
10kHz - 100kHz
Recovered Clock Jitter
Transfer Corner Frequency
Peaking Amplitude
36
43
76
ITU-G.823
UIp-p
ITU-G.736
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 60: E1 RECEIVER ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
Jitter Attenuator Corner Frequency
JABW = 0
JABW = 1
Return Loss
51kHz - 102kHz
102kHz - 2048kHz
2048kHz - 3072kHz
MIN
TYP
MAX
UNIT
TEST CONDITION
-
10
1.5
-
Hz
Hz
ITU-G.736
14
20
16
-
-
dB
dB
dB
ITU-G.703
TABLE 61: T1 RECEIVER ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
MIN
TYP
MAX
UNIT
TEST CONDITION
Number of consecutive zeros
before RLOS is declared
100
175
250
Input signal level at RLOS
15
20
-
dB
12.5
-
-
% ones
Receiver Sensitivity (short haul
with cable loss)
12
-
-
dB
With nominal pulse amplitude of
3.0V for 100Ω termination.
Receiver Sensitivity (long haul
with cable loss)
0
-
36
dB
With nominal pulse amplitude of
3.0V for 100Ω termination.
Input Impedance
-
13
-
kΩ
138
0.4
-
-
UIp-p
UIp-p
-
9.8
-
0.1
kHz
dB
TR-TSY-000499
-
6
-
Hz
AT&T Pub 62411
-
20
25
25
-
dB
dB
dB
Receiver Loss of Signal
RLOS clear
Input Jitter Tolerance
1Hz
10kHz - 100kHz
Recovered Clock Jitter
Transfer Corner Frequency
Peaking Amplitude
Jitter Attenuator Corner Frequency
Return Loss
51kHz - 102kHz
102kHz - 2048kHz
2048kHz - 3072kHz
77
Cable attenuation @ 772kHz
ITU-G.775, ETSI 300 233
AT&T Pub 62411
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
TABLE 62: E1 TRANSMITTER ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
MIN
TYP
MAX
UNIT
2.185
2.76
2.37
3.00
2.555
3.24
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
14
10
-
-
dB
dB
dB
AMI Output Pulse Amplitude
75Ω
120Ω
Jitter Added by the Transmitter
Output
Output Return Loss
51kHz - 102kHz
102kHz - 2048kHz
2048kHz - 3072kHz
TEST CONDITION
1:2 Transformer
Broad Band with jitter free TCLK
applied to the input.
ETSI 300 166, CHPTT
TABLE 63: T1 TRANSMITTER ELECTRICAL CHARACTERISTICS
VDD=3.3V ±5%, TA=25°C, UNLESS OTHERWISE SPECIFIED
PARAMETER
MIN
TYP
MAX
UNIT
AMI Output Pulse Amplitude
2.5
3.0
3.5
V
1:2 Transformer measured at
DSX-1
Output Pulse Width
338
350
362
ns
ANSI T1.102
Output Pulse Width Imbalance
-
-
20
Output Pulse Amplitude Imbalance
-
-
±200
mV
Jitter Added by the Transmitter
Output
-
0.025
0.05
UIp-p
-
15
15
15
-
dB
dB
dB
Output Return Loss
51kHz - 102kHz
102kHz - 2048kHz
2048kHz - 3072kHz
78
TEST CONDITION
ANSI T1.102
ANSI T1.102
Broad Band with jitter free TCLK
applied to the input.
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
ORDERING INFORMATION
PRODUCT NUMBER
PACKAGE
OPERATING TEMPERATURE RANGE
XRT83L314IB
304 LEAD TBGA
-400C to +850C
PACKAGE DIMENSIONS (DIE DOWN)
22
23
20
21
18
19
16
17
14
15
12
13
10
11
8
9
6
7
4
5
A1
Feature/Mark
2
3
1
A
B
C
D
E
F
G
H
J
K
L
D
D1
M
N
P
R
T
U
V
W
Y
AA
AB
AC
D1
D
(A1 corner feature is mfger option)
P
SEATING PLANE
e
A1
A
A2
b
Note: The control dimension is in millimeter.
SYMBOL
A
A1
A2
P
D
D1
b
e
INCHES
MIN
MAX
0.051
0.067
0.018
0.028
0.031
0.071
0.004
0.012
1.213
1.228
1.100 BSC
0.024
0.035
0.050 BSC
79
MILLIMETERS
MIN
MAX
1.30
1.70
0.45
0.70
0.80
1.80
0.10
0.30
30.80
31.20
27.94 BSC
0.60
0.90
1.27 BSC
XRT83L314
14-CHANNEL T1/E1/J1 LONG-HAUL/SHORT-HAUL LINE INTERFACE UNIT
REV. 1.0.0
REVISION HISTORY
REVISION #
DATE
DESCRIPTION
P1.0.0
02/14/03
First release of the 14-Channel LIU Preliminary Datasheet
P1.0.1
03/27/03
Added the 16-bit LCV Counter Details for Revision B Silicon
P1.0.2
09/19/03
Changed the Microprocessor Access Timing Parameters
P1.0.3
11/12/03
Added new E1 arbitrary pulse feature. Added descriptions to the global registers.
1.0.0
05/04/04
Final Release.
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 2004 EXAR Corporation
Datasheet May 2004.
Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited.
80