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DS21448DALLASN/a267avai3.3V E1/T1/J1 Quad Line Interface


DS21448 ,3.3V E1/T1/J1 Quad Line InterfaceAPPLICATIONS CSU Line Build-Outs for T1 Integrated Multiservice Access Platforms AMI, HDB3, and B ..
DS21448DK ,3.3V E1/T1/J1 Line Interface Design Kit Daughter CardFEATURES The DS21448DK is an easy-to-use evaluation board Demonstrates Key Functions of the DS214 ..
DS21448L ,3.3V E1/T1/J1 Quad Line Interfaceapplications). Intel or Motorola  Detects/Generates Blue (AIS) Alarms The DS21448 has diagnostic ..
DS21448L+ ,3.3V E1/T1/J1 Quad Line InterfacePIN DESCRIPTION .....7 3. DETAILED DESCRIPTION 13 3.1 DS21448 AND DS21Q348 DIFFERENCES.....13 4. PO ..
DS21448L+W ,3.3V E1/T1/J1 Quad Line InterfaceAPPLICATIONS CSU Line Build-Outs for T1 Integrated Multiservice Access Platforms AMI, HDB3, and B ..
DS21448LN ,3.3V E1/T1/J1 Quad Line InterfaceBlock Diagram.. 5 Figure 1-2. Receive Logic Detail.. 6 Figure 1-3. Transmit Logic Detail. 6 Figure ..


DS21448
3.3V E1/T1/J1 Quad Line Interface
GENERAL DESCRIPTION
The DS21448 is a quad-port E1 or T1 line interface
unit (LIU) for short-haul and long-haul applications. It
incorporates four independent transmitters and four
independent receivers in a single 144-pin PBGA or
128-pin LQFP package. The transmit drivers
generate the necessary G.703 E1 waveshapes in
75Ω or 120Ω applications and the DSX-1 or CSU line
build-outs of 0dB, -7.5dB, -15dB, and -22.5dB for T1
applications.
APPLICATIONS

Integrated Multiservice Access Platforms
T1/E1 Cross-Connects, Multiplexers, and Channel
Banks
Central-Office Switches and PBX Interfaces
T1/E1 LAN/WAN Routers
Wireless Base Stations
ORDERING INFORMATION
PART* TEMP RANGE PIN-PACKAGE

DS21448 0°C to +70°C 144 TE-PBGA
DS21448+ 0°C to +70°C 144 TE-PBGA
DS21448N -40°C to +85°C 144 TE-PBGA
DS21448N+ -40°C to +85°C 144 TE-PBGA
DS21448L 0°C to +70°C 128 LQFP
DS21448L+ 0°C to +70°C 128 LQFP
DS21448LN -40°C to +85°C 128 LQFP
DS21448LN+ -40°C to +85°C 128 LQFP
+ Denotes lead-free/RoHS-compliant package.
*All devices rated at 3.3V.
Pin Configurations appear in Section 11.
FEATURES
� Four Complete E1, T1, or J1 LIUs � Supports Long- and Short-Haul Trunks � Internal Software-Selectable Receive-Side
Termination for 75Ω/100Ω/120Ω � 3.3V Power Supply � 32-Bit or 128-Bit Crystal-Less Jitter Attenuator
Requires Only a 2.048MHz Master Clock for E1
and T1, with the Option to Use 1.544MHz for T1 � Generates the Appropriate Line Build-Outs With
and Without Return Loss for E1, and DSX-1 and
CSU Line Build-Outs for T1 � AMI, HDB3, and B8ZS Encoding/Decoding � 16.384MHz, 8.192MHz, 4.096MHz, or 2.048MHz
Clock Output Synthesized to Recovered Clock � Programmable Monitor Mode for Receiver � Loopbacks and PRBS Pattern Generation/
Detection with Output for Received Errors � Generates/Detects In-Band Loop Codes, 1 to 16
Bits, Including CSU Loop Codes � 8-Bit Parallel or Serial Interface with Optional
Hardware Mode � Muxed and Nonmuxed Parallel Bus Supports
Intel or Motorola � Detects/Generates Blue (AIS) Alarms � NRZ/Bipolar Interface for Tx/Rx Data I/O � Transmit Open-Circuit Detection � Receive Carrier Loss (RCL) Indication (G.775) � High-Z State for TTIP and TRING � 50mARMS Transmit Current Limiter � JTAG Boundary Scan Test Port per IEEE 1149.1 � Meets Latest E1 and T1 Specifications Including
ANSI.403-1999, ANSI T1.408, AT&T TR 62411,
ITU G.703, G.704, G.706, G.736, G.775, G.823,
I.431, O.151, O.161, ETSI ETS 300 166,
JTG.703, JTI.431, TBR12, TBR13, and CTR4
DS21448
3.3V E1/T1/J1 Quad Line Interface

DS21448 3.3V T1/E1/J1 Quad Line Interface
TABLE OF CONTENTS

1. BLOCK DIAGRAMS........................................................................................................................5
2. PIN DESCRIPTION..........................................................................................................................7
3. DETAILED DESCRIPTION............................................................................................................13

3.1 DS21448 AND DS21Q348 DIFFERENCES......................................................................................13
4. PORT OPERATION.......................................................................................................................14

4.1 HARDWARE MODE.........................................................................................................................14
4.2 SERIAL PORT OPERATION..............................................................................................................15
4.3 PARALLEL PORT OPERATION.........................................................................................................18
4.3.1 Device Power-Up and Reset................................................................................................................18
4.3.2 Register Map........................................................................................................................................18
4.3.3 Control Registers.................................................................................................................................19
5. STATUS REGISTERS....................................................................................................................23
6. DIAGNOSTICS ..............................................................................................................................28

6.1 IN-BAND LOOP-CODE GENERATION AND DETECTION......................................................................28
6.2 LOOPBACKS..................................................................................................................................31
6.2.1 Remote Loopback (RLB).....................................................................................................................31
6.2.2 Local Loopback (LLB)..........................................................................................................................31
6.2.3 Analog Loopback (LLB).......................................................................................................................31
6.2.4 Dual Loopback (DLB)...........................................................................................................................31
6.3 PRBS GENERATION AND DETECTION............................................................................................31
6.4 ERROR COUNTER..........................................................................................................................31
6.5 ERROR COUNTER UPDATE............................................................................................................32
6.6 ERROR INSERTION........................................................................................................................32
7. ANALOG INTERFACE...................................................................................................................33

7.1 RECEIVER.....................................................................................................................................33
7.2 TRANSMITTER...............................................................................................................................33
7.3 JITTER ATTENUATOR.....................................................................................................................34
7.4 G.703 SYNCHRONIZATION SIGNAL.................................................................................................34
8. JTAG BOUNDARY SCAN ARCHITECTURE AND TEST ACCESS PORT..................................43

8.1 JTAG TAP CONTROLLER STATE MACHINE....................................................................................43
8.2 INSTRUCTION REGISTER................................................................................................................45
8.3 TEST REGISTERS..........................................................................................................................46
9. OPERATING PARAMETERS........................................................................................................48
10. AC TIMING PARAMETERS AND DIAGRAMS..............................................................................49
11. PIN CONFIGURATIONS................................................................................................................56

11.1 144-PIN BGA............................................................................................................................56
11.2 128-PIN LQFP...........................................................................................................................57
12. PACKAGE INFORMATION...........................................................................................................58

12.1 144-BALL TE-PBGA (56-G6020-001).......................................................................................58
12.2 128-PIN LQFP (56-G4011-001)................................................................................................59
13. THERMAL INFORMATION............................................................................................................60
14. REVISION HISTORY......................................................................................................................60
DS21448 3.3V T1/E1/J1 Quad Line Interface
LIST OF FIGURES

Figure 1-1. Block Diagram..........................................................................................................................5
Figure 1-2. Receive Logic Detail................................................................................................................6
Figure 1-3. Transmit Logic Detail...............................................................................................................6
Figure 4-1. Serial Port Operation for Read Access (R = 1) Mode 1.........................................................16
Figure 4-2. Serial Port Operation for Read Access (R = 1) Mode 2.........................................................16
Figure 4-3. Serial Port Operation for Read Access (R = 1) Mode 3.........................................................16
Figure 4-4. Serial Port Operation for Read Access (R = 1) Mode 4.........................................................17
Figure 4-5. Serial Port Operation for Write Access (R = 0) Modes 1 and 2..............................................17
Figure 4-6. Serial Port Operation for Write Access (R = 0) Modes 3 and 4..............................................17
Figure 7-1. Basic Interface.......................................................................................................................36
Figure 7-2. Protected Interface Using Internal Receive Termination........................................................37
Figure 7-3. Protected Interface Using External Receive Termination.......................................................38
Figure 7-4. Dual Connector-Protected Interface Using Receive Termination...........................................39
Figure 7-5. E1 Transmit Pulse Template..................................................................................................40
Figure 7-6. T1 Transmit Pulse Template..................................................................................................41
Figure 7-7. Jitter Tolerance......................................................................................................................42
Figure 7-8. Jitter Attenuation....................................................................................................................42
Figure 8-1. JTAG Block Diagram..............................................................................................................43
Figure 8-2. TAP Controller State Diagram................................................................................................44
Figure 10-1. Intel Bus Read Timing (PBTS = 0, BIS0 = 0).......................................................................49
Figure 10-2. Intel Bus Write Timing (PBTS = 0, BIS0 = 0).......................................................................50
Figure 10-3. Motorola Bus Timing (PBTS = 1, BIS0 = 0)..........................................................................50
Figure 10-4. Intel Bus Read Timing (PBTS = 0, BIS0 = 1).......................................................................51
Figure 10-5. Intel Bus Write Timing (PBTS = 0, BIS0 = 1).......................................................................52
Figure 10-6. Motorola Bus Read Timing (PBTS = 1, BIS0 = 1)................................................................52
Figure 10-7. Motorola Bus Write Timing (PBTS = 1, BIS0 = 1)................................................................52
Figure 10-8. Serial Bus Timing (BIS1 = 1, BIS0 = 0)................................................................................53
Figure 10-9. Receive-Side Timing............................................................................................................54
Figure 10-10. Transmit-Side Timing.........................................................................................................55
DS21448 3.3V T1/E1/J1 Quad Line Interface
LIST OF TABLES

Table 2-A. Bus Interface Selection.............................................................................................................7
Table 2-B. Pin Assignments.......................................................................................................................7
Table 2-C. Parallel Interface Mode Pin Description....................................................................................9
Table 2-D. Serial Interface Mode Pin Description....................................................................................10
Table 2-E. Hardware Interface Mode Pin Description..............................................................................11
Table 3-A. DS21448 vs. DS21Q348 Pin Differences...............................................................................13
Table 4-A. Loopback Control in Hardware Mode.....................................................................................14
Table 4-B. Transmit Data Control in Hardware Mode...............................................................................14
Table 4-C. Receive Sensitivity Settings in Hardware Mode.....................................................................14
Table 4-D. Monitor Gain Settings in Hardware Mode...............................................................................14
Table 4-E. Internal Rx Termination Select in Hardware Mode.................................................................14
Table 4-F. MCLK Selection in Hardware Mode........................................................................................15
Table 4-G. Parallel Port Mode Selection..................................................................................................18
Table 4-H. Register Map..........................................................................................................................18
Table 4-I. Receive Sensitivity Settings.....................................................................................................22
Table 4-J. Backplane Clock Select...........................................................................................................22
Table 4-K. Monitor Gain Settings.............................................................................................................22
Table 4-L. Internal Rx Termination Select................................................................................................22
Table 5-A. Received Alarm Criteria..........................................................................................................25
Table 5-B. Receive Level Indication.........................................................................................................27
Table 6-A. Transmit Code Length............................................................................................................29
Table 6-B. Receive Code Length.............................................................................................................29
Table 6-C. Definition of Received Errors..................................................................................................32
Table 6-D. Function of ECRS Bits and RNEG Pin....................................................................................32
Table 7-A. Line Build-Out Select for E1 in Register CCR4 (ETS = 0)......................................................34
Table 7-B. Line Build-Out Select for T1 in Register CCR4 (ETS = 1)......................................................34
Table 7-C. Line Build-Out Select for E1 in Register CCR4 (ETS = 0) Using Alternate Transformer
Configuration......................................................................................................................................35
Table 7-D. Transformer Specifications (3.3V Operation)..........................................................................35
Table 8-A. Instruction Codes for IEEE 1149.1 Architecture.....................................................................45
Table 8-B. ID Code Structure...................................................................................................................46
Table 8-C. Device ID Codes.....................................................................................................................46
Table 8-D. Boundary Scan Control Bits....................................................................................................47
Table 10-A. AC Characteristics—Multiplexed Parallel Port (BIS0 = 0).....................................................49
Table 10-B. AC Characteristics—Nonmultiplexed Parallel Port (BIS0 = 1)..............................................51
Table 10-C. AC Characteristics—Serial Port (BIS1 = 1, BIS0 = 0)...........................................................53
Table 10-D. AC Characteristics—Receive Side.......................................................................................54
Table 10-E. AC Characteristics—Transmit Side......................................................................................55
Table 13-A. Thermal Characteristics—BGA.............................................................................................60
Table 13-B. Theta-JA (θJA) vs. Airflow—BGA...........................................................................................60
Table 13-C. Thermal Characteristics—LQFP...........................................................................................60
Table 13-D. Theta-JA (θJA) vs. Airflow—LQFP.........................................................................................60
DS21448 3.3V T1/E1/J1 Quad Line Interface
1. BLOCK DIAGRAMS

Figure 1-1. Block Diagram

POWER
CONNECTIONS 2
VCO/PLL
MCL
2.048MHz TO
1.544MHz PLL
JITTER
ATTENUATOR
MUX
VSM
TRING
TTIP
FILTER RRING
RTIP
UNFRAMED
ALL-ONES
INSERTION
BIS0
CONTROL AND TEST
PORT (ROUTED TO
ALL BLOCKS) MUX (THE SERIAL, PARALLEL, AND HARDWARE INTERFACES
SHARE DEVICE PINS) HRST
TXDIS/TEST
16.384MHz OR
8.192MHz OR
4.096MHz OR
2.048MHz
SYNTHESIZER
BPCLK
RPOS
RCLK
RNEG
TPOS
TCLK
TNEG
JACLK
MUX
See Figure 1-2
See Figure 1-3
PBEO
MUX RCL/LOTC
TYPICAL OF ALL FOUR CHANNELS CHANNEL 1
CHANNEL 2
CHANNEL 3
CHANNEL 4
JRSTJTMS
JTDI
JTDO
JTAG PORT
JTCL 5
CONTROL AND
(ROUTED TO
ALL BLOCKS) PARALLEL INTERFACE
SD
SERIAL
INTERFACE
PBTS
(R/
(DS
ALE
TO D7
TO AD7
OPTIONAL
TERM
INANATION
ALOG LOO
PBAC
INE
DRIV
U FIL
AVESH
APIN
PEAK D
TEC
OCK
/DA
COV
REMOTE
LOOP
CK
(DU
AL MOD
CAL LO
BAC
JITTER ATTENUATIO
BE PL
IN
EITH
TR
IT O
TE L
OOPB
Dallas
Semiconductor

DS21448
DS21448 3.3V T1/E1/J1 Quad Line Interface
Figure 1-2. Receive Logic Detail

Figure 1-3. Transmit Logic Detail

RPOS
RNEG
FROM
REMOTE
LOOPBACK
CLOCK
INVERT
RCLK
CCR2.0
CCR1.6
ROUTED TO
ALL BLOCKS
MUX
4 OR 8 ZERO DETECT
16 ZERO DETECT
RIR1.7 RIR1.6
B8ZS/HDB3
DECODER
ALL-ONES
DETECTOR
LOOP CODE
DETECTOR
PRBS
DETECTOR
SR.6SR.7SR.4RIR1.3
CCR2.3
RIR1.5
16-BIT ERROR
COUNTER (ECR)
MUX CCR6.0SR.0
CCR6.2/
CCR6.0/
CCR6.1
NRZ DATA
BPV/CV/EXZ
PBEO
CCR1.4
BPV
INSERT MUX
B8ZS/ HDB3
CODER
LOGIC
ERROR
INSERT
MUX
OR
GATE
OR
GA TE CCR3.1
CCR1.6
CCR2.2
CCR3.0
CCR3.4CCR3.3
TPOS
TNEG
TO REMOTE
LOOPBACK
PRBS
GENERATOR
LOOP CODE
GENERATOR
CLOCK
INVERT
LOSS-OF-TRANSMIT
CLOCK DETECT
TCLK
CCR2.1
RCLK JACLK
(FROM MCLK)
CCR1.0
CCR1.1
CCR1.2
MUX MUX
OR
GA TE
TO LOTC OUTPUT PIN
AND
GATE
ROUTED TO
ALL BLOCKS
SR.5
DS21448 3.3V T1/E1/J1 Quad Line Interface
2. PIN DESCRIPTION

The DS21448 can be controlled in parallel port mode, serial port mode, or hardware mode. The bus interface select
bits 0 and 1 (BIS0, BIS1) determine the device mode and pin assignments (Table 2-A).
Table 2-A. Bus Interface Selection
BIS1 BIS0 BUS INTERFACE TYPE
0 Parallel Port Mode (multiplexed) 1 Parallel Port Mode (nonmultiplexed) 0 Serial Port Mode
1 1 Hardware Mode
Table 2-B. Pin Assignments
PIN
BGA LQFP I/O PARALLEL PORT MODE SERIAL PORT MODE HARDWARE MODE

J3 18 I CS1 CS1 EGL1
D3 57 I CS2 CS2 EGL2
D10 84 I CS3 CS3 EGL3
K10 114 I CS4 CS4 EGL4
J2 91 I RD (DS) N/A ETS
H1 92 I WR (R/W) N/A NRZE
K2 95 I ALE (AS) N/A SCLKE
J1 35 I N/A SCLK L2
K3 36 I N/A SDI L1
K1 62 I/O A4 SDO L0
L1 63 I A3 ICES DJA
H11 64 I A2 OCES JAMUX
H12 65 I A1 N/A JAS
G12 66 I A0 N/A HBE
J10 75 I/O D7/AD7 N/A CES
H10 76 I/O D6/AD6 N/A TPD
G11 77 I/O D5/AD5 N/A TX0
J9 78 I/O D4/AD4 N/A TX1
E3 79 I/O D3/AD3 N/A LOOP0
D4 80 I/O D2/AD2 N/A LOOP1
F3 81 I/O D1/AD1 N/A MM0
D5 82 I/O D0/AD0 N/A MM1
— 3 I VSM VSM VSM
L5 115–117 — VDD1 VDD1 VDD1
E4 19–21 — VDD2 VDD2 VDD2
D8 49–51 — VDD3 VDD3 VDD3
J8 85–87 — VDD4 VDD4 VDD4
M4 118–120 — VSS1 VSS1 VSS1
F4 22–24 — VSS2 VSS2 VSS2
D9 52–54 — VSS3 VSS3 VSS3
H9 88–90 — VSS4 VSS4 VSS4
K9 97 I/O INT INT RT1
K5 110 O PBEO1 PBEO1 PBEO1
G3 111 O PBEO2 PBEO2 PBEO2
E10 121 O PBEO3 PBEO3 PBEO3
K8 123 O PBEO4 PBEO4 PBEO4
L6 126 O RCL1/LOTC1 RCL1/LOTC1 RCL1
D7 128 O RCL2/LOTC2 RCL2/LOTC2 RCL2
F9 1 O RCL3/LOTC3 RCL3/LOTC3 RCL3
J7 2 O RCL4/LOTC4 RCL4/LOTC4 RCL4
K7 98 I TXDIS/TEST TXDIS/TEST TXDIS/TEST
A1 124 I RTIP1 RTIP1 RTIP1
A4 28 I RTIP2 RTIP2 RTIP2
A7 60 I RTIP3 RTIP3 RTIP3
A10 93 I RTIP4 RTIP4 RTIP4
DS21448 3.3V T1/E1/J1 Quad Line Interface
PIN
BGA LQFP I/O PARALLEL PORT MODE SERIAL PORT MODE HARDWARE MODE

B8 61 I RRING3 RRING3 RRING3
B11 94 I RRING4 RRING4 RRING4
L9 106 I HRST HRST HRST
J6 109 I MCLK MCLK MCLK
H4 122 O BPCLK1 BPCLK1 BPCLK1
D6 47 O BPCLK2 BPCLK2 BPCLK2
F10 56 O BPCLK3 BPCLK3 BPCLK3
L8 112 O BPCLK4 BPCLK4 BPCLK4
L7 107 I BIS0 BIS0 BIS0
M8 68 I BIS1 BIS1 BIS1
A2 6 O TTIP1 TTIP1 TTIP1
A5 38 O TTIP2 TTIP2 TTIP2
A8 71 O TTIP3 TTIP3 TTIP3
A11 102 O TTIP4 TTIP4 TTIP4
J4 7 — TVSS1 TVSS1 TVSS1
D1 39 — TVSS2 TVSS2 TVSS2
E9 72 — TVSS3 TVSS3 TVSS3
L10 103 — TVSS4 TVSS4 TVSS4
J5 8 — TVDD1 TVDD1 TVDD1
D2 40 — TVDD2 TVDD2 TVDD2
G9 73 — TVDD3 TVDD3 TVDD3
M9 104 — TVDD4 TVDD4 TVDD4
B3 9 O TRING1 TRING1 TRING1
B6 41 O TRING2 TRING2 TRING2
B9 74 O TRING3 TRING3 TRING3
B12 105 O TRING4 TRING4 TRING4
K4 10 O RPOS1 RPOS1 RPOS1
E1 12 O RPOS2 RPOS2 RPOS2
D11 14 O RPOS3 RPOS3 RPOS3
K11 16 O RPOS4 RPOS4 RPOS4
G2 11 O RNEG1 RNEG1 RNEG1
E2 13 O RNEG2 RNEG2 RNEG2
F11 15 O RNEG3 RNEG3 RNEG3
M10 25 O RNEG4 RNEG4 RNEG4
H3 127 O RCLK1 RCLK1 RCLK1
F1 31 O RCLK2 RCLK2 RCLK2
E11 58 O RCLK3 RCLK3 RCLK3
L11 96 O RCLK4 RCLK4 RCLK4
G1 26 I TPOS1 TPOS1 TPOS1
F2 30 I TPOS2 TPOS2 TPOS2
E12 33 I TPOS3 TPOS3 TPOS3
M11 55 I TPOS4 TPOS4 TPOS4
H2 27 I TNEG1 TNEG1 TNEG1
M1 32 I TNEG2 TNEG2 TNEG2
D12 34 I TNEG3 TNEG3 TNEG3
K12 59 I TNEG4 TNEG4 TNEG4
M2 17 I TCLK1 TCLK1 TCLK1
L2 43 I TCLK2 TCLK2 TCLK2
F12 83 I TCLK3 TCLK3 TCLK3
L12 113 I TCLK4 TCLK4 TCLK4
M12 108 I PBTS N/A RT0
L3 42 I JTRST JTRST JTRST
M3 48 I JTMS JTMS JTMS
M5 44 I JTCLK JTCLK JTCLK
M6 45 I JTDI JTDI JTDI
M7 46 O JTDO JTDO JTDO
Note 1: The VSM signal is not available with the BGA package option.
Note 2: The LQFP no-connect pin numbers are 4, 5, 37, 67, 69, 70, and 99–101.
Note 3: The BGA no-connect pin numbers are A3, A6, A9, A12, B1, B4, B7, B10, C1–C12, E5–E8, F5–F8, G4–G8, G10, H5–H8, J11, J12, K6,
DS21448 3.3V T1/E1/J1 Quad Line Interface
Table 2-C. Parallel Interface Mode Pin Description
PIN I/O FUNCTION

RD (DS) I Read Input (Data Strobe). RD and DS are active-low signals. DS is active low when in
nonmultiplexed, Motorola mode. See the bus timing diagrams in Section 10.
WR (R/W) I Write Input (Read/Write). WR is an active-low signal. See the bus timing diagrams in Section 10.
ALE (AS) I
Address Latch Enable (Address Strobe). When using multiplexed bus mode (BIS0 = 0), this pin
serves to demultiplex the bus on a positive-going edge. In nonmultiplexed bus mode (BIS0 = 1),
ALE should be wired low.
A4–A0 I Address Bus. In nonmultiplexed bus operation (BIS0 = 1), these pins serve as the address bus.
In multiplexed bus operation (BIS0 = 0), these pins are not used and should be wired low.
D7/AD7–D0/AD0 I/O
Data Bus/Address/Data Bus. In nonmultiplexed bus operation (BIS0 = 1), these pins serve as the
data bus. In multiplexed bus operation (BIS0 = 0), these pins serve as an 8-bit multiplexed
address/data bus.
INT O Interrupt (INT). The interrupt flags the host controller during conditions and change of conditions
defined in the status register. It is an active-low, open-drain output.
TXDIS/TEST I
Tri-State Control, Multifunctional. Set this pin high, with all CS1–CS4 inputs inactive, to tri-state
TTIP1–TTIP4 and TRING1–TRING4. Set this pin high with any of the CS1–CS4 inputs active to
tri-state all outputs and I/O pins (including the parallel control port). Set low for normal operation.
HRST I Hardware Reset. Bringing HRST low resets the DS21448, setting all control bits to the all-zeros
default state.
MCLK I
Master Clock. A 2.048MHz (±50ppm) clock source with TTL levels is applied at this pin. This
clock is used internally for both clock/data recovery and for jitter attenuation. Use of a T1
1.544MHz clock source is optional (Note 1).
BIS0/BIS1 I Bus Interface Select Bit 0 and 1. Used to select bus interface option. See Table 2-A for details.
PBTS I
Parallel Bus Type Select. When using the parallel port, set PBTS high to select Motorola bus
timing; set low to select Intel bus timing. This pin controls the function of the RD (DS), ALE (AS),
and WR (R/W) pins.
Chip Select 1. Must be low to read or write to channel 1 of the device. CS1 is an active-low
signal.
Chip Select 2. Must be low to read or write to channel 2 of the device. CS2 is an active-low
signal.
Chip Select 3. Must be low to read or write to channel 3 of the device. CS3 is an active-low
signal.
CS1–CS4 I
Chip Select 4. Must be low to read or write to channel 4 of the device. CS4 is an active-low
signal.
PBEO1–PBEO4 O
PRBS Bit-Error Output. The receiver constantly searches for a 215 - 1 (E1) or a QRSS (T1)
PRBS, depending on the ETS bit setting (CCR1.7). It remains high if it is out of synchronization
with the PRBS pattern. It goes low when synchronized to the PRBS pattern. Any errors in the
received pattern after synchronization cause a positive-going pulse (with same period as E1 or
T1 clock) synchronous with RCLK. PRBS bit errors can also be reported to the ECR1 and ECR2
registers by setting CCR6.2 to logic 1.
RCL1/LOTC1–
RCL4/LOTC4 O
Receive Carrier Loss/Loss-of-Transmit Clock. An output that toggles high during a receive carrier
loss (CCR2.7 = 0) or toggles high if the TCLK pin has not been toggled for 5µs ± 2µs (CCR2.7 =
1). CCR2.7 defaults to logic 0 when in hardware mode.
RTIP1–RTIP4 I
RRING1–RRING4 I
Receive Tip and Ring. Analog inputs for clock recovery circuitry. These pins connect through a
1:1 transformer to the line. See Section 7 for details.
BPCLK1–BPCLK4 O Backplane Clock. A 16.384MHz, 8.192MHz, 4.096MHz, or 2.048MHz clock output that is
referenced to RCLK selectable through CCR5.7 and CCR5.6.
TTIP1–TTIP4 O
TRING1–TRING4 O
Transmit Tip and Ring. Analog line-driver outputs. These pins connect through a step-up
transformer to the line. See Section 7 for details.
RPOS1–RPOS4 O
Receive Positive Data. These bits are updated on the rising edge (CCR2.0 = 0) or the falling
edge (CCR2.0 = 1) of RCLK with bipolar data out of the line interface. Set NRZE (CCR1.6) to 1
for NRZ applications. In NRZ mode, data is output on RPOS, and a received error (BPV, CV, or
EXZ) causes a positive-going pulse synchronous with RCLK at RNEG.
RNEG1–RNEG4 O
Receive Negative Data. Updated on the rising edge (CCR2.0 = 0) or the falling edge (CCR2.0 =
1) of RCLK with the bipolar data out of the line interface. Set NRZE (CCR1.6) to 1 for NRZ
applications. In NRZ mode, data is output on RPOS, and a received error (BPV, CV, or EXZ)
causes a positive-going pulse synchronous with RCLK at RNEG.
DS21448 3.3V T1/E1/J1 Quad Line Interface
PIN I/O FUNCTION

RCLK1–RCLK4 O Receive Clock. Buffered recovered clock from the line. Synchronous to MCLK in absence of
signal at RTIP and RRING.
TPOS1–TPOS4 I Transmit Positive Data. Sampled on the falling edge (CCR2.1 = 0) or the rising edge
(CCR2.1 = 1) of TCLK for data to be transmitted out onto the line.
TNEG1–TNEG4 I Transmit Negative Data. Sampled on the falling edge (CCR2.1 = 0) or the rising edge
(CCR2.1 = 1) of TCLK for data to be transmitted out onto the line.
TCLK1–TCLK4 I
Transmit Clock. A 2.048MHz or 1.544MHz primary clock. It is used to clock data through the
transmit-side formatter. It can be sourced internally by MCLK or RCLK. See Common Control
Register 1 and Figure 1-3.
JTRST I JTAG Reset
JTMS I JTAG Mode Select
JTCLK I JTAG Clock
JTDI I JTAG Data In
JTDO O JTAG Data Out
VSM I Voltage Supply Mode (LQFP only). Should be wired low for correct operation.
TVDD1–TVDD4 — 3.3V, ±5% Transmitter Positive Supply
VDD1–VDD4 — 3.3V, ±5% Positive Supply
TVSS1–TVSS4 — Transmitter Signal Ground
VSS1–VSS4 — Signal Ground
Table 2-D. Serial Interface Mode Pin Description
PIN I/O FUNCTION

INT I/O Interrupt (INT). Flags host controller during conditions and change of conditions defined in the
status register. Active-low, open-drain output.
TXDIS/TEST I
Tri-State Control, Multifunctional. Set this pin high with all CS1–CS4 inputs inactive to tri-state
TTIP1–TTIP4 and TRING1–TRING4. Set this pin high with any of the CS1–CS4 inputs active to
tri-state all outputs and I/O pins (including the parallel control port). Set low for normal operation.
HRST I Hardware Reset. Bringing HRST low resets the DS21448, setting all control bits to the all-zeros
default state.
MCLK I
Master Clock. A 2.048MHz (±50ppm) clock source with TTL levels is applied at this pin. This
clock is used internally for both clock/data recovery and for jitter attenuation. A T1 1.544MHz
clock source is optional (Note 1).
BIS0/BIS1 I Bus Interface Select Bit 0 and 1. Used to select bus interface option. See Table 2-A for details.
CS1 I Chip Select 1. Must be low to read or write to channel 1 of the device. CS1 is an active-low
signal.
CS2 I Chip Select 2. Must be low to read or write to channel 2 of the device. CS2 is an active-low
signal.
CS3 I Chip Select 3. Must be low to read or write to channel 3 of the device. CS3 is an active-low
signal.
CS4 I Chip Select 4. Must be low to read or write to channel 4 of the device. CS4 is an active-low
signal.
ICES I Input Clock-Edge Select. Selects whether the serial interface data input (SDI) is sampled on the
rising (ICES = 0) or falling edge (ICES = 1) of SCLK.
OCES I Output Clock-Edge Select. Selects whether the serial interface data output (SDO) changes on
the rising (OCES = 1) or falling edge (OCES = 0) of SCLK.
SCLK I Serial Clock. Serial interface clock.
SDI I Serial Data Input. Serial interface data input.
SDO O Serial Data Output. Serial interface data output.
PBEO1–PBEO4 O
PRBS Bit-Error Output. The receiver constantly searches for a 215 - 1 (E1) or a QRSS (T1)
PRBS, depending on the ETS bit setting (CCR1.7). It remains high if it is out of synchronization
with the PRBS pattern. It goes low when synchronized to the PRBS pattern. Any errors in the
received pattern after synchronization cause a positive-going pulse (with same period as E1 or
T1 clock) synchronous with RCLK. PRBS bit errors can also be reported to the ECR1 and ECR2
registers by setting CCR6.2 to logic 1.
RCL1/LOTC1–
RCL4/LOTC4 O
Receive Carrier Loss/Loss-of-Transmit Clock. An output that toggles high during a receive carrier
loss (CCR2.7 = 0) or toggles high if the TCLK pin has not been toggled for 5µs ± 2µs
(CCR2.7 = 1). CCR2.7 defaults to logic 0 when in hardware mode.
RTIP1–RTIP4 Receive Tip and Ring. Analog inputs for clock recovery circuitry. These pins connect through a
DS21448 3.3V T1/E1/J1 Quad Line Interface
PIN I/O FUNCTION

BPCLK1–BPCLK4 O Backplane Clock. A 16.384MHz, 8.192MHz, 4.096MHz, or 2.048MHz clock output that is
referenced to RCLK selectable through CCR5.7 and CCR5.6.
TTIP1–TTIP4 O
TRING–TRING4 O
Transmit Tip and Ring. Analog line-driver outputs. These pins connect through a step-up
transformer to the line. See Section 7 for details.
RPOS1–RPOS4 O
Receive Positive Data. Updated on the rising edge (CCR2.0 = 0) or the falling edge (CCR2.0 = 1)
of RCLK with bipolar data out of the line interface. Set NRZE (CCR1.6) to 1 for NRZ applications.
In NRZ mode, data is output on RPOS, and a received error (BPV, CV, or EXZ) causes a
positive-going pulse synchronous with RCLK at RNEG.
RNEG1–RNEG4 O
Receive Negative Data. Updated on the rising edge (CCR2.0 = 0) or the falling edge (CCR2.0 =
1) of RCLK with the bipolar data out of the line interface. Set NRZE (CCR1.6) to 1 for NRZ
applications. In NRZ mode, data is output on RPOS, and a received error (BPV, CV, or EXZ)
causes a positive-going pulse synchronous with RCLK at RNEG.
RCLK1–RCLK4 O Receive Clock. Buffered recovered clock from the line. Synchronous to MCLK in absence of
signal at RTIP and RRING.
TPOS1–TPOS4 I Transmit Positive Data. Sampled on the falling edge (CCR2.1 = 0) or the rising edge (CCR2.1 =
1) of TCLK for data to be transmitted out onto the line.
TNEG1–TNEG4 I Transmit Negative Data. Sampled on the falling edge (CCR2.1 = 0) or the rising edge (CCR2.1 =
1) of TCLK for data to be transmitted out onto the line.
TCLK1–TCLK4 I
Transmit Clock. A 2.048MHz or 1.544MHz primary clock used to clock data through the transmit
side formatter. They can be sourced internally by MCLK or RCLK. See Common Control Register
1 and Figure 1-3.
JTRST I JTAG Reset
JTMS I JTAG Mode Select
JTCLK I JTAG Clock
JTDI I JTAG Data In
JTDO O JTAG Data Out
VSM I Voltage Supply Mode (LQFP only). VSM should be wired low for correct operation.
TVDD1–TVDD4 — 3.3V, ±5% Transmitter Positive Supply
VDD1–VDD4 — 3.3V, ±5% Positive Supply
TVSS1–TVSS4 — Transmitter Signal Ground for Transmitter Outputs
VSS1–VSS4 — Signal Ground
Table 2-E. Hardware Interface Mode Pin Description
PIN I/O FUNCTION

ETS I
E1/T1 Select
0 = E1
1 = T1
NRZE I
NRZ Enable
0 = bipolar data at RPOS/RNEG and TPOS/TNEG
1 = NRZ data at RPOS and TPOS or TNEG; RNEG outputs a positive-going pulse when the
device receives a BPV, CV, or EXZ.
SCLKE I
Receive and Transmit Synchronization Clock Enable. SCLKE combines RSCLKE (CCR5.3) and
TSCLKE (CCR5.2).
0 = disable 2.048MHz synchronization transmit and receive mode
1 = enable 2.048MHz synchronization transmit and receive mode
DJA I
Disable Jitter Attenuator
0 = jitter attenuator enabled
1 = jitter attenuator disabled
JAMUX I
Jitter Attenuator Clock Mux. Controls the source for JACLK.
0 = JACLK sourced from MCLK (2.048MHz or 1.544MHz at MCLK).
1 = JACLK sourced from internal PLL (2.048 MHz at MCLK).
JAS I
Jitter Attenuator Path Select
0 = place the jitter attenuator on the receive side
1 = place the jitter attenuator on the transmit side
HBE I
Receive and Transmit HDB3/B8ZS Enable. HBE combines RHBE (CCR2.3) and THBE
(CCR2.2).
0 = enable HDB3 (E1)/B8ZS (T1)
1 = disable HDB3 (E1)/B8ZS (T1) Line Build-Out Select Bits 0,1, and 2. These pins set the transmitter build-out; see (Table 7-A
DS21448 3.3V T1/E1/J1 Quad Line Interface
PIN I/O FUNCTION

CES I
Receive and Transmit Clock Select. Selects which RCLK edge to update RPOS and RNEG and
which TCLK edge to sample TPOS and TNEG. CES combines TCES and RCES.
0 = update RPOS/RNEG on rising edge of RCLK; sample TPOS/TNEG on falling edge of TCLK
1 = update RPOS/RNEG on falling edge of RCLK; sample TPOS/TNEG on rising edge of TCLK
TPD I
Transmit Power-Down
0 = normal transmitter operation
1 = powers down the transmitter and tri-states TTIP and TRING pins
TX0/TX1 I Transmit Data Source Select Bits 0 and 1. These inputs determine the source of the transmit
data (Table 4-B).
LOOP0/LOOP1 I Loopback Select Bits 0 and 1. These inputs determine the active loopback mode (Table 4-A).
MM0/MM1 I Monitor Mode Select Bits 0 and 1. These inputs determine if the receive equalizer is in a monitor
mode (Table 4-D).
RT1/RT0 I Receive LIU Termination Select Bits 0 and 1. These inputs determine the receive termination
(Table 4-E).
TEST I Tri-State Control. Set high to tri-state all outputs and I/O pins (including the parallel control port).
Set low for normal operation. Useful in board-level testing.
HRST I Hardware Reset. Bringing HRST low resets the DS21448, setting all control bits to the all-zero
default state.
MCLK I
Master Clock. A 2.048MHz (±50ppm) clock source with TTL levels is applied at this pin. This
clock is used internally for both clock/data recovery and for jitter attenuation. A T1 1.544MHz
clock source is optional (Note 1). See Table 4-F for details.
BIS0/BIS1 I Bus Interface Select Bit 0 and 1. Used to select bus interface option (Table 2-A).
EGL1–EGL4 I Receive Equalizer Gain-Limit Select. These bits control the sensitivity of the receive equalizers
(Table 4-C).
PBEO1–PBEO4 O
PRBS Bit-Error Output. The receiver constantly searches for a 215 - 1 PRBS (ETS = 0) or a
QRSS PRBS (ETS = 1). The pattern is chosen automatically by the value of the ETS pin. It
remains high if it is out of synchronization with the PRBS pattern. It goes low when synchronized
to the PRBS pattern. Any errors in the received pattern after synchronization cause a positive-
going pulse (with same period as E1 or T1 clock) synchronous with RCLK.
RCL1–RCL4 O Receive Carrier Loss. An output that toggles high during a receive carrier loss.
RTIP1–RTIP4 I
RRING1–RRING4 I
Receive Tip and Ring. Analog inputs for clock recovery circuitry. These pins connect through a
1:1 transformer to the line. See Section 7 for details.
BPCLK1–BPCLK4 O Backplane Clock. A 16.384MHz clock output that is referenced to RCLK.
TTIP1–TTIP4
TRING1–TRING4 O Transmit Tip and Ring. Analog line-driver outputs. These pins connect through a step-up
transformer to the line. See Section 7 for details.
RPOS1–RPOS4 O
Receive Positive Data. Updated on the rising edge (CES = 0) or the falling edge (CES = 1) of
RCLK with bipolar data out of the line interface. In NRZ mode (NRZE = 1), data is output on
RPOS, and a received error (BPV, CV, or EXZ) causes a positive-going pulse synchronous with
RCLK at RNEG.
RNEG1–RNEG4 O
Receive Negative Data. Updated on the rising edge (CES = 0) or the falling edge (CES = 1) of
RCLK with bipolar data out of the line interface. In NRZ mode (NRZE = 1), data is output on
RPOS, and a received error (BPV, CV, or EXZ) causes a positive-going pulse synchronous with
RCLK at RNEG.
RCLK1–RCLK4 O Receive Clock. Buffered recovered clock from the line. Synchronous to MCLK in absence of
signal at RTIP and RRING.
TPOS1–TPOS4 I Transmit Positive Data. Sampled on the falling edge (CES = 0) or the rising edge (CES = 1) of
TCLK for data to be transmitted out onto the line.
TNEG1–TNEG4 I Transmit Negative Data. Sampled on the falling edge (CES = 0) or the rising edge (CES = 1) of
TCLK for data to be transmitted out onto the line.
TCLK1–TCLK4 I
Transmit Clock. A 2.048MHz or 1.544MHz primary clock used to clock data through the transmit
side formatter. It can be sourced internally by MCLK or RCLK. See Common Control Register 1
and Figure 1-3.
JTRST I JTAG Reset
JTMS I JTAG Mode Select
JTCLK I JTAG Clock
JTDI I JTAG Data In
JTDO O JTAG Data Out
VSM I Voltage Supply Mode (LQFP only). VSM should be wired low for correct operation.
DS21448 3.3V T1/E1/J1 Quad Line Interface
PIN I/O FUNCTION

TVSS1–TVSS4 — Transmitter Signal Ground for Transmitter Outputs
VSS1–VSS4 — Signal Ground
Note 1: G.703 requires an accuracy of ±50ppm for T1 and E1. TR62411 and ANSI specs require ±32ppm accuracy for T1 interfaces.

3. DETAILED DESCRIPTION

The DS21448 has a usable receiver sensitivity of 0 to -43dB for E1 applications and 0 to -36dB for T1 that allows it
to operate on 0.63mm (22AWG) cables up to 2.5km (E1) and 6000ft (T1) in length. The user has the option to use
internal receive termination, software selectable for 75Ω, 100Ω, and 120Ω applications, or external termination.
The on-board crystal-less jitter attenuator can be placed in either the transmit or the receive data path, and requires
only a 2.048MHz MCLK for both E1 and T1 applications (with the option of using a 1.544MHz MCLK in T1
applications).
The DS21448 has diagnostic capabilities such as loopbacks and PRBS pattern generation and detection. 16-bit
loop-up and loop-down codes can be generated and detected. A single input pin can power down all transmitters to
allow the implementation of hitless protection switching (HPS) for 1+1 redundancy without the use of relays. The
device can be controlled through an 8-bit parallel port (muxed or nonmuxed) or a serial port, and it can be used in
hardware mode. A standard boundary scan interface supports board-level testing.
The DS21448 contains four independent LIUs that share a common interface for configuration and status. The user
can choose between three different means of accessing the device: a parallel microprocessor interface, a serial
interface, and a hardwired mode, which configures the device by setting levels on the device’s pins. The
DS21448’s four chip selects (CS1, CS2, CS3, and CS4) determine which LIU is accessed when using the parallel
or serial interface modes. Four sets of identical register maps exist, one for each channel. Using the appropriate
chip select accesses a channel’s register map.
The analog AMI/HDB3 waveform off the E1 line or the AMI/B8ZS waveform off the T1 line is transformer-coupled
into the RTIP and RRING pins of the DS21448. The user has the option to use internal termination, software
selectable for 75Ω/100Ω/120Ω applications, or external termination. The device recovers clock and data from the
analog signal and passes it through the jitter attenuation mux, outputting the received line clock at RCLK and
bipolar or NRZ data at RPOS and RNEG. The DS21448 contains an active filter that reconstructs the analog-
received signal for the nonlinear losses that occur in transmission. The receive circuitry is also configurable for
various monitor applications. The device has a usable receive sensitivity of 0 to -43dB for E1 and 0 to -36dB for T1
that allows the device to operate on 0.63mm (22AWG) cables up to 2.5km (E1) and 6k feet (T1) in length. Data
input at TPOS and TNEG is sent through the jitter attenuation mux to the waveshaping circuitry and line driver. The
DS21448 drives the E1 or T1 line from the TTIP and TRING pins through a coupling transformer. The line driver
can handle both CEPT 30/ISDN-PRI lines for E1 and long-haul (CSU) or short-haul (DSX-1) lines for T1.
3.1 DS21448 and DS21Q348 Differences

The DS21448 BGA is a monolithic quad-port LIU that is a replacement for the DS21Q348. The additional features
of JTAG, transmit driver disable, and the serial interface in the DS21448 have changed the function of several pins,
as shown in Table 3-A.
Table 3-A. DS21448 vs. DS21Q348 Pin Differences
PIN DS21Q348 DS21448

G4 VSM N.C.
J1 VSS SCLK
K1 A4 A4/SDO
K3 VSS SDI
K7 TEST TXDIS/TEST
L3 N.C. JTRST*
M3 N.C. JTMS*
M5 N.C. JTCLK
M6 N.C. JTDI*
M7 N.C. JTDO
DS21448 3.3V T1/E1/J1 Quad Line Interface
4. PORT OPERATION
4.1 Hardware Mode

The DS21448 supports a hardware configuration mode that allows the user to configure the device by setting levels
on the device’s pins. This mode allows the DS21448 configuration without the use of a microprocessor, simplifying
designs. Not all of the device features are supported in the hardware mode.
In hardware mode (BIS0 = 1, BIS1 = 1) several pins have been redefined so they can be used for initializing the
DS21448. Refer to Table 2-B and Table 2-E for pin assignment and definition. Because of limited pin count, several
functions have been combined and affect all four channels in the device and/or treat the receive and transmit paths
as one block. Restrictions when using the hardware mode include the following: • BPCLK pins only output a 16.384MHz signal. • The RCL/LOTC pins are designated to RCL. • The RHBE and THBE control bits are combined and controlled by HBE. • RSCLKE and TSCLKE bits are combined and controlled by SCLKE. • TCES and RCES are combined and controlled by CES. • The transmitter functions are combined and controlled by TX1 and TX0. • Loopback functions are controlled by LOOP1 and LOOP0. • JABDS defaults to 128-bit buffer depth. • All other control bits default to logic 0.
Table 4-A. Loopback Control in Hardware Mode
LOOPBACK SYMBOL LOOP1 LOOP0

Remote Loopback RLB 1 1
Local Loopback LLB 1 0
Analog Loopback ALB 0 1
No Loopback — 0 0
Table 4-B. Transmit Data Control in Hardware Mode
TRANSMIT DATA SYMBOL TX1 TX0

Unframed All Ones TUA1 1 1
Alternating Ones and Zeros TAOZ 1 0
PRBS TPRBSE 0 1
TPOS and TNEG — 0 0
Table 4-C. Receive Sensitivity Settings in Hardware Mode
EGL ETS RECEIVE SENSITIVITY (dB)
0 (E1) -12 (short haul) 0 (E1) -43 (long haul) 1 (T1) -30 (limited long haul) 1 (T1) -36 (long haul)
Table 4-D. Monitor Gain Settings in Hardware Mode
MM1 MM0 INTERNAL LINEAR GAIN BOOST (dB)
0 Normal operation (no boost)
0 1 20
1 0 26
1 1 32
Table 4-E. Internal Rx Termination Select in Hardware Mode
RT1 RT0 INTERNAL RECEIVE
TERMINATION CONFIGURATION
0 Internal receive-side termination disabled 1 Internal receive-side 120Ω enabled
DS21448 3.3V T1/E1/J1 Quad Line Interface
Table 4-F. MCLK Selection in Hardware Mode
MCLK (MHz) JAMUX ETS

2.048 0 0
2.048 1 1
1.544 0 1
4.2 Serial Port Operation

Setting BIS1 = 1 and BIS0 = 0 enables the serial bus interface on the DS21448 (Table 2-A). Serial port read/write
timing is unrelated to the system transmit and receive timing, allowing asynchronous reads or writes by the host.
See Section 10 for the AC timing of the serial port. All serial port accesses are LSB first. See Figure 4-1,
Figure 4-2, Figure 4-3, Figure 4-4, Figure 4-5, and Figure 4-6 for additional details.
A serial bus access requires the use of four signals: serial clock (SCLK), one of the four chip selects (CS), serial
data input (SDI), and serial data output (SDO). The DS21448 uses SCLK to sample data that is present on SDI and
output data onto SDO. Input clock-edge select (ICES) allows the user to choose which SCLK edge input data is
sampled on. Output clock-edge select (OCES) allows the user to choose which SCLK edge output data changes
on. When ICES is low, input data is latched on the rising edge of SCLK, and when ICES is high, input data is
latched on the falling edge of SCLK. When OCES is low, data is output on the falling edge of SCLK, and when
OCES is high, data is output on the rising edge of SCLK. Data is held until the next falling or rising edge of SCLK.
All data transfers are initiated by driving the appropriate port’s CS input low and ends with CS going inactive. CS
must go inactive between data transfers. See the serial bus timing information in Section 10 for details. All data
transfers are terminated if the port’s CS input transitions high. Port control logic is disabled, and SDO is tri-stated
when all CS pins are inactive.
Reading from or writing to the internal registers requires writing one address/command byte prior to the transferring
register data. Two types of serial bus transfers exist, standard and burst. The standard serial bus access always
consists of two bytes, an address/command byte that is always supplied by the user on SDI, and a data byte that
can either be written to the DS21448 using SDI (write operation) or output by the DS21448 on SDO (read
operation). The burst serial bus access consists of a single address/command byte followed either by 22 read or 22
write data bytes.
The first bit written (LSB) of the address/command byte specifies whether the access is to be a read (1) or a write
(0). The next 5 bits identify the register address. Valid register addresses are 00h through 15h. Bit 7 is reserved
and must be set to 0 for proper operation. Bit 8, the last bit (MSB) of the address/command byte, is the burst mode-
enable bit. When the burst bit is enabled (set to 0) and a READ operation is performed, the DS21448 automatically
outputs the contents of registers 00h through 15h sequentially, starting with register address 00h. When the burst
bit is enabled and a WRITE operation is performed, data supplied on SDI is sequentially written into the DS21448’s
register space starting at address 00h. Burst operation is stopped once address 15h is read or CS goes inactive.
For both burst read and burst write transfers, the address/command byte’s register address bits must be set to 0.
The user can broadcast register write accesses to multiple ports simultaneously by enabling the desired channels’
chip selects at the same time. However, only one port can be read at a time. Any attempt to read multiple ports
simultaneously results in invalid data being returned on SDO.
DS21448 3.3V T1/E1/J1 Quad Line Interface
Figure 4-1. Serial Port Operation for Read Access (R = 1) Mode 1

Figure 4-2. Serial Port Operation for Read Access (R = 1) Mode 2

Figure 4-3. Serial Port Operation for Read Access (R = 1) Mode 3
2 3 4 5 6 7891011121314 15 16
1 A1 A2 A3 A4 A5 0BD2D3D4D5 D6
SCLK
SDI
SDO
CS
(LSB) (MSB)
(LSB)
(MSB)
READ ACCESS ENABLED
ICES = 1 (SAMPLE SDI ON THE FALLING EDGE OF SCLK)
OCES = 1 (UPDATE SDO ON RISING EDGE OF SCLK) 2 3 4 5 6 7891011121314 15 16
1 A1 A2 A3 A4 A5 0BD2D3D4 D5 D6
SCLK
SDI
SDO
CS
(LSB) (MSB)
(LSB)
(MSB)
ICES = 1 (SAMPLE SDI ON THE FALLING EDGE OF SCLK)
OCES = 0 (UPDATE SDO ON FALLING EDGE OF SCLK)
ICES = 0 (SAMPLE SDI ON THE RISING EDGE OF SCLK)
OCES = 0 (UPDATE SDO ON FALLING EDGE OF SCLK) 2 3 4 5 6 7891011121314 15 16
1 A1 A2 A3 A4 A5 0 BD2D3D4D5 D6
SCLK
SDI
SDO
CS
(LSB) (MSB)
(LSB)
D7
(MSB)
DS21448 3.3V T1/E1/J1 Quad Line Interface
Figure 4-4. Serial Port Operation for Read Access (R = 1) Mode 4

Figure 4-5. Serial Port Operation for Write Access (R = 0) Modes 1 and 2

Figure 4-6. Serial Port Operation for Write Access (R = 0) Modes 3 and 4

ICES = 0 (SAMPLE SDI ON THE RISING EDGE OF SCLK)
OCES = 1 (UPDATE SDO ON RISING EDGE OF SCLK) 2 3 4 5 6 7891011121314 15 16
1 A1 A2 A3 A4 A5 0 B
SCLK
SDI
SDO
CS
(LSB) (MSB)
(LSB)(MSB)D2D3D4D5 D6 D0D72 3 4 5 6 7891011121314 15 16SCLK
CS
0 A1 A2 A3 A4 A5 0B
(MSB)
SDI
SDO
D1D2D3 D4 D5 D7
(LSB)(MSB) D6
(LSB)
WRITE ACCESS ENABLED
ICES = 1 (SAMPLE SDI ON THE FALLING EDGE OF SCLK) 2 3 4 5 6 7891011121314 15 16SCLK
CS
0 A1 A2 A3 A4 A5 0 B
(MSB)
SDI
SDO
D1D2D3 D4 D5 D7
(LSB)(MSB) D6
(LSB)
WRITE ACCESS ENABLED
ICES = 0 (SAMPLE SDI ON THE RISING EDGE OF SCLK)
DS21448 3.3V T1/E1/J1 Quad Line Interface
4.3 Parallel Port Operation

The option for either multiplexed bus operation (BIS0 = 0) or nonmultiplexed bus operation (BIS0 = 1) is available
when using the parallel interface. The DS21448 can operate with either Intel or Motorola bus timing configurations.
If the PBTS pin is wired low, Intel timing is selected; if wired high, Motorola timing is selected. All Motorola bus
signals are listed in parentheses (). Four sets of identical register maps exist, one for each channel. See Table 4-H
for register names and addresses. Use the appropriate chip select (CS1, CS2, CS3, or CS4) to access a channel’s
register map. See the timing diagrams in Section 10 for more details. Hardware and serial port modes are not
supported when using parallel port operation.
4.3.1 Device Power-Up and Reset

The DS21448 resets itself upon power-up, setting all writeable registers to 00h and clearing the status and
information registers. CCR3.7 (TUA1) = 0 results in the LIU transmitting unframed all ones. After the power
supplies have settled, initialize all control registers to the desired settings, then toggle the LIRST bit (CCR3.2). The
DS21448 can at any time be reset to the default settings by bringing HRST low (level triggered) or by powering
down and powering up again.
Table 4-G. Parallel Port Mode Selection
PBTS BIS0 PROCESSOR BUS INTERFACE TYPE
0 Intel Parallel Port Mode (Multiplexed) 1 Intel Parallel Port Mode (Nonmultiplexed) 0 Motorola Parallel Port Mode (Multiplexed) 1 Motorola Parallel Port Mode (Nonmultiplexed)
4.3.2 Register Map

Table 4-H shows the typical register map for all four ports. Use the appropriate chip select (CS1, CS2, CS3, or CS4)
to access a channel’s register map.
Table 4-H. Register Map
NAME R/W ADDRESS FUNCTION

CCR1 R/W 00h Common Control Register 1
CCR2 R/W 01h Common Control Register 2
CCR3 R/W 02h Common Control Register 3
CCR4 R/W 03h Common Control Register 4
CCR5 R/W 04h Common Control Register 5
CCR6 R/W 05h Common Control Register 6
SR R 06h Status Register
IMR R/W 07h Interrupt Mask Register
RIR1 R 08h Receive Information Register 1
RIR2 R 09h Receive Information Register 2
IBCC R/W 0Ah In-Band Code Control Register
TCD1 R/W 0Bh Transmit Code Definition Register 1
TCD2 R/W 0Ch Transmit Code Definition Register 2
RUPCD1 R/W 0Dh Receive-Up Code Definition Register 1
RUPCD2 R/W 0Eh Receive-Up Code Definition Register 2
RDNCD1 R/W 0Fh Receive-Down Code Definition Register 1
RDNCD2 R/W 10h Receive-Down Code Definition Register 2
ECR1 R 11h Error Count Register 1
ECR2 R 12h Error Count Register 2
TEST1 R/W 13h Test 1
TEST2 R/W 14h Test 2
TEST2 R/W 15h Test 3
— — (Note 1) —
Note 1: Register addresses 16h–1Fh do not exist.

DS21448 3.3V T1/E1/J1 Quad Line Interface
4.3.3 Control Registers

CCR1 (00H): Common Control Register 1
(MSB)
(LSB)
ETS NRZE RCLA ECUE JAMUX TTOJ TTOR LOTCMC
NAME POSITION FUNCTION

ETS CCR1.7
E1/T1 Select
0 = E1
1 = T1
NRZE CCR1.6
NRZ Enable
0 = bipolar data at RPOS/RNEG and TPOS/TNEG
1 = NRZ data at RPOS and TPOS or TNEG; RNEG outputs a positive-going pulse when the
device receives a BPV, CV, or EXZ
RCLA CCR1.5
Receive-Carrier-Loss Alternate Criteria
0 = RCL declared upon 255 (E1) or 192 (T1) consecutive zeros
1 = RCL declared upon 2048 (E1) or 1544 (T1) consecutive zeros
ECUE CCR1.4
Error Counter Update Enable. A 0-to-1 transition forces the next receive clock cycle to load the
error counter registers with the latest counts and reset the counters. The user must wait a
minimum of two clock cycles (976ns for E1 and 1296ns for T1) before reading the error count
registers to allow for a proper update. See Section 6 for details.
JAMUX CCR1.3
Jitter Attenuator Clock Mux. Controls the source for JACLK (Figure 1-1).
0 = JACLK sourced from MCLK (2.048MHz or 1.544MHz at MCLK)
1 = JACLK sourced from internal PLL (2.048MHz at MCLK)
TTOJ CCR1.2
TCLK to JACLK. Internally connects TCLK to JACLK (Figure 1-3).
0 = disabled
1 = enabled
TTOR CCR1.1
TCLK to RCLK. Internally connects TCLK to RCLK (Figure 1-3).
0 = disabled
1 = enabled
LOTCMC CCR1.0
Loss-of-Transmit Clock Mux Control. Determines whether the transmit logic should switch to
JACLK if the TCLK input should fail to transition (Figure 1-3).
0 = do not switch to JACLK if TCLK stops
1 = switch to JACLK if TCLK stops
DS21448 3.3V T1/E1/J1 Quad Line Interface
CCR2 (01H): Common Control Register 2
(MSB)
(LSB)
RLPIN — SCLD CLDS RHBE THBE TCES RCES
NAME POSITION FUNCTION

RLPIN CCR2.7
RCL/LOTC Pin Function Select. Forced to logic 0 in hardware mode.
0 = toggles high during a receive-carrier loss condition
1 = toggles high if TCLK does not transition for at least 5µs CCR2.6 Not Assigned. Should be set to 0 when written to.
SCLD CCR2.5
Short Circuit-Limit Disable (ETS = 0). Controls the 50mA (RMS) current limiter.
0 = enable 50mA current limiter
1 = disable 50mA current limiter
CLDS CCR2.4
Custom Line-Driver Select. Setting this bit to 1 redefines the operation of the transmit line
driver. When this bit is set to 1 and CCR4.5 = CCR4.6 = CCR4.7 = 0, the device generates a
square wave at the TTIP and TRING outputs instead of a normal waveform. When this bit is
set to 1 and CCR4.5 = CCR4.6 = CCR4.7 ≠ 0, the device forces TTIP and TRING outputs to
become open-drain drivers instead of their normal push-pull operation. This bit should be set
to 0 for normal operation of the device. Contact the factory for more details about how to use
this bit.
RHBE CCR2.3
Receive HDB3/B8ZS Enable
0 = enable HDB3 (E1)/B8ZS (T1)
1 = disable HDB3 (E1)/B8ZS (T1)
THBE CCR2.2
Transmit HDB3/B8ZS Enable
0 = enable HDB3 (E1)/B8ZS (T1)
1 = disable HDB3 (E1)/B8ZS (T1)
TCES CCR2.1
Transmit Clock-Edge Select. Selects which TCLK edge to sample TPOS and TNEG.
0 = sample TPOS and TNEG on falling edge of TCLK
1 = sample TPOS and TNEG on rising edge of TCLK
RCES CCR2.0
Receive Clock-Edge Select. Selects which RCLK edge to update RPOS and RNEG.
0 = update RPOS and RNEG on rising edge of RCLK
1 = update RPOS and RNEG on falling edge of RCLK
DS21448 3.3V T1/E1/J1 Quad Line Interface
CCR3 (02H): Common Control Register 3
(MSB)
(LSB)
TUA1 ATUA1 TAOZ TPRBSE TLCE LIRST IBPV IBE
NAME POSITION FUNCTION

TUA1 CCR3.7
Transmit Unframed All Ones. The polarity of this bit is set such that the device transmits an all-
ones pattern on power-up or device reset. This bit must be set to 1 to allow the device to transmit
data. The transmission of this data pattern is always timed off JACLK (Figure 1-1).
0 = transmit all ones at TTIP and TRING
1 = transmit data normally
ATUA1 CCR3.6
Automatic Transmit Unframed All Ones. Automatically transmit an unframed all-ones pattern at
TTIP and TRING during an RCL condition.
0 = disabled
1 = enabled
TAOZ CCR3.5
Transmit Alternate Ones and Zeros. Transmit a …101010… pattern at TTIP and TRING. The
transmission of this data pattern is always timed off TCLK.
0 = disabled
1 = enabled
TPRBSE CCR3.4
Transmit PRBS Enable. Transmit a 215 - 1 (E1) or a QRSS (T1) PRBS at TTIP and TRING.
0 = disabled
1 = enabled
TLCE CCR3.3
Transmit Loop-Code Enable. Enables the transmit side to transmit the loop-up code in the transmit
code definition registers (TCD1 and TCD2). See Section 6 for details.
0 = disabled
1 = enabled
LIRST CCR3.2
Line Interface Reset. Setting this bit from 0 to 1 initiates an internal reset that resets the clock
recovery state machine and recenters the jitter attenuator. Normally this bit is only toggled on
power-up. It must be cleared and set again for a subsequent reset.
IBPV CCR3.1
Insert Bipolar Violation (BPV). A 0-to-1 transition on this bit causes a single bipolar violation to be
inserted into the transmit data stream. Once this bit has been toggled from 0 to 1, the device waits
for the next occurrence of three consecutive 1s to insert the BPV. This bit must be cleared and set
again for a subsequent error to be inserted (Figure 1-3).
IBE CCR3.0
Insert Bit Error. A 0-to-1 transition on this bit causes a single logic error to be inserted into the
transmit data stream. This bit must be cleared and set again for a subsequent error to be inserted
(Figure 1-3).
CCR4 (03H): Common Control Register 4
(MSB)
(LSB)
L2 L1 L0 EGL JAS JABDS DJA TPD
NAME POSITION FUNCTION

L2 CCR4.7 Line Build-Out Select Bit 2. Sets the transmitter build-out (Table 7-A for E1, Table 7-B for T1).
L1 CCR4.6 Line Build Out Select Bit 1. Sets the transmitter build-out (Table 7-A for E1, Table 7-B for T1).
L0 CCR4.5 Line Build Out Select Bit 0. Sets the transmitter build-out (Table 7-A for E1, Table 7-B for T1).
EGL CCR4.4 Receive Equalizer Gain Limit. This bit controls the sensitivity of the receive equalizer (Table 4-I).
JAS CCR4.3
Jitter Attenuator Path Select
0 = place the jitter attenuator on the receive side
1 = place the jitter attenuator on the transmit side
JABDS CCR4.2
Jitter Attenuator Buffer Depth Select
0 = 128 bits
1 = 32 bits (use for delay-sensitive applications)
DJA CCR4.1
Disable Jitter Attenuator
0 = jitter attenuator enabled
1 = jitter attenuator disabled
TPD CCR4.0
Transmit Power-Down
0 = normal transmitter operation
1 = powers down the transmitter and tri-states the TTIP and TRING pins
DS21448 3.3V T1/E1/J1 Quad Line Interface
Table 4-I. Receive Sensitivity Settings
EGL
(CCR4.4)
ETS
(CCR1.7)
RECEIVE SENSITIVITY
(dB)
0 (E1) -12 (short haul) 0 (E1) -43 (long haul) 1 (T1) -30 (limited long haul) 1 (T1) -36 (long haul)
CCR5 (04H): Common Control Register 5
(MSB)
(LSB)
BPCS1 BPCS0 MM1 MM0 RSCLKE TSCLKE RT1 RT0
NAME POSITION FUNCTION

BPCS1 CCR5.7 Backplane Clock Frequency Select 1. See Table 4-J for details.
BPCS0 CCR5.6 Backplane Clock Frequency Select 0. See Table 4-J for details.
MM1 CCR5.5 Monitor Mode Gain Select 1 (Table 4-K. )
MM0 CCR5.4 Monitor Mode Gain Select 0. See (Table 4-K.
RSCLKE CCR5.3
Receive Synchronization Clock Enable
0 = disable 2.048MHz synchronization receive mode
1 = enable 2.048MHz synchronization receive mode
TSCLKE CCR5.2
Transmit Synchronization Clock Enable
0 = disable 2.048MHz transmit synchronization clock
1 = enable 2.048MHz transmit synchronization clock
RT1 CCR5.1 Receive Termination Select 1. See Table 4-L for details.
RT0 CCR5.0 Receive Termination Select 0. See Table 4-L for details.
Table 4-J. Backplane Clock Select
BPCS1
(CCR5.7)
BPCS0
(CCR5.6) BPCLK FREQUENCY (MHz)

0 0 16.384
0 1 8.192
1 0 4.096
1 1 2.048
Table 4-K. Monitor Gain Settings
MM1
(CCR5.5)
MM0
(CCR5.4)
INTERNAL LINEAR GAIN
BOOST (dB)
0 Normal operation (no boost)
0 1 20
1 0 26
1 1 32
Table 4-L. Internal Rx Termination Select
RT1
(CCR5.1)
RT0
(CCR5.0)
INTERNAL RECEIVE
TERMINATION CONFIGURATION
0 Internal receive-side termination disabled
0 1 Internal receive-side 120Ω enabled
1 0 Internal receive-side 100Ω enabled
1 1 Internal receive-side 75Ω enabled
DS21448 3.3V T1/E1/J1 Quad Line Interface
CCR6 (05H): Common Control Register 6
(MSB)
(LSB)
LLB RLB ARLBE ALB RJAB ECRS2 ECRS1 ECRS0
NAME POSITION FUNCTION

LLB CCR6.7
Local Loopback. In local loopback, transmit data is looped back to the receive path, passing
through the jitter attenuator if it is enabled. Data in the transmit path acts as normal. See
Section 6.2 for details.
0 = loopback disabled
1 = loopback enabled
RLB CCR6.6
Remote Loopback. In remote loopback, data output from the clock/data recovery circuitry is
looped back to the transmit path, passing through the jitter attenuator if it is enabled. Data in
the receive path acts as normal, while data presented at TPOS and TNEG is ignored. See
Section 6.2 for details.
0 = loopback disabled
1 = loopback enabled
ARLBE CCR6.5
Automatic Remote Loopback Enable and Reset. When this bit is set high, the device
automatically goes into remote loopback when it detects loop-up code programmed into the
receive loop-up code definition registers (RUPCD1 and RUPCD2) for a minimum of 5
seconds; it also sets the RIR2.1 status bit. Once it is in an RLB state, the bit remains in this
state until it has detected the loop code programmed into the receive loop-down code
definition registers (RDNCD1 and RDNCD2) for a minimum of 5 seconds, at which point it
forces the device out of RLB and clears RIR2.1. Toggling this bit from 1 to 0 resets the
automatic RLB circuitry. The action of the automatic remote loopback circuitry is logically
ORed with the RLB (CCR6.6) control bit (i.e., either one can cause a RLB to occur).
ALB CCR6.4
Analog Loopback. In analog loopback, signals at TTIP and TRING are internally connected to
RTIP and RRING. The incoming line signals at RTIP and RRING are ignored. The signals at
TTIP and TRING are transmitted as normal. See Section 6.2 for more details.
0 = loopback disabled
1 = loopback enabled
RJAB CCR6.3
RCLK Jitter Attenuator Bypass. This control bit allows the receive-recovered clock and data to
bypass the jitter attenuation, while still allowing the BPCLK output to use the jitter attenuator.
See Section 7.3 for details.
0 = disabled
1 = enabled
ECRS2 CCR6.2 Error Count Register Select 2. See Section 6.4 for details.
ECRS1 CCR6.1 Error Count Register Select 1. See Section 6.4 for details.
ECRS0 CCR6.0 Error Count Register Select 0. See Section 6.4 for details.
5. STATUS REGISTERS

The three registers that contain information about the device’s real-time status are the status register (SR) and
receive information registers 1 and 2 (RIR1/RIR2). When a particular event has occurred (or is occurring), the
appropriate bit in one of these registers is set to 1. Some bits in SR, RIR1, and RIR2 are latched bits and some are
real-time bits (denoted in the following register descriptions). For latched status bits, when an event or an alarm
occurs, the bit is set to 1 and remains set until the user reads that bit. The bit is cleared when it is read, and it is not
set until the event has occurred again. Two of the latched status bits (RUA1 and RCL) remain set after reading if
the alarm is still present.
The user always precedes a read of any of the three status registers with a write. The byte written to the register
informs the DS21448 which bits the user wishes to read and have cleared. The user writes a byte to one of these
registers with a 1 in the bit positions to be read and a 0 in the other bit positions. When a 1 is written to a bit
location, that location is updated with the latest information. When a 0 is written to a bit position, that bit position is
not updated, and the previous value is held. A write to the status and information registers is immediately followed
by a read of the same register. The read result should be logically ANDed with the mask byte that was just written,
and this value should be written back into the same register to ensure that bit does indeed clear. This second write
step is necessary because the alarms and events in the status registers occur asynchronously with respect to their
access through the parallel port. This write-read-write scheme allows an external microcontroller or microprocessor
to individually poll certain bits without disturbing the other bits in the register. This operation is key in controlling the
DS21448 with higher-order software languages.
DS21448 3.3V T1/E1/J1 Quad Line Interface
The bits in the SR register have the unique ability to initiate a hardware interrupt through the INT output pin. Each
of the alarms and events in the SR can be either masked or unmasked from the interrupt pin through the interrupt
mask register (IMR). The interrupts caused by the RCL, RUA1, and LOTC bits in the SR act differently than the
interrupts caused by the other status bits in the SR. The RCL, RUA1, and LOTC bits forces the INT pin low
whenever they change state (i.e., go active or inactive). The INT pin is allowed to return high (if no other interrupts
are present) when the user reads the alarm bit that caused the interrupt to occur, even if the alarm is still present.
The other status bits in the SR can force the INT pin low when they are set. The INT pin is allowed to return high (if
no other interrupts are present) when the user reads the event bit that caused the interrupt to occur.
The host can quickly determine which of the four LIU channels is generating an interrupt by reading one of the
unused addresses in the 16h–1Fh range in any LIU channel. See the following LIU channel interrupt status
description for additional information.
LIU Channel Interrupt Status
(MSB)
(LSB)
— — — — LIU4 LIU3 LIU2 LIU1
NAME POSITION FUNCTION

N/A 7 Not Assigned. Could be any value when read.
N/A 6 Not Assigned. Could be any value when read.
N/A 5 Not Assigned. Could be any value when read.
N/A 4 Not Assigned. Could be any value when read.
LIU4 3 LIU4 Status Register. A 1 in this bit position indicates that the status register (SR) in channel 4 is
asserting an interrupt.
LIU3 2 LIU3 Status Register. A 1 in this bit position indicates that the status register (SR) in channel 3 is
asserting an interrupt.
LIU2 1 LIU2 Status Register. A 1 in this bit position indicates that the status register (SR) in channel 2 is
asserting an interrupt.
LIU1 0 LIU1 Status Register. A 1 in this bit position indicates that the status register (SR) in channel 1 is
asserting an interrupt.
SR (06H): Status Register
(MSB)
(LSB)
LUP LDN LOTC RUA1 RCL TCLE TOCD PRBSD
NAME POSITION FUNCTION

LUP
(Latched) SR.7 Loop-Up Code Detected. This bit is set when the loop-up code defined in registers RUPCD1 and
RUPCD2 is being received. See Section 6.1 for details.
LDN
(Latched) SR.6 Loop-Down Code Detected. This bit is set when the loop-down code defined in registers
RDNCD1 and RDNCD2 is being received. See Section 6.1 for details.
LOTC
(Real Time) SR.5 Loss-of-Transmit Clock. This bit is set when the TCLK pin has not transitioned for 5µs (±2µs),
forcing the LOTC pin high.
RUA1
(Latched) SR.4 Receive Unframed All Ones. This bit is set when an unframed all-ones code is received at RRING
and RTIP (Table 5-A).
RCL
(Latched) SR.3 Receive Carrier Loss. This bit is set when an RCL condition exists at RRING and RTIP. See
(Table 5-A) for details.
TCLE
(Real Time) SR.2 Transmit Current-Limit Exceeded. This bit is set when the 50mA (RMS) current limiter is activated
whether or not the current limiter is enabled.
TOCD
(Real Time) SR.1 Transmit Open-Circuit Detect. This bit is set when the device detects that the TTIP and TRING
outputs are open circuited.
PRBSD
(Real Time) SR.0 PRBS Detect. This bit is set when the receive side detects a 215 - 1 (E1) or a QRSS (T1)
pseudorandom bit sequence (PRBS).
DS21448 3.3V T1/E1/J1 Quad Line Interface
Table 5-A. Received Alarm Criteria
ALARM E1/T1 SET CRITERIA CLEAR CRITERIA

RUA1 E1 Fewer than two 0s in two frames (512 bits) More than two 0s in two frames (512 bits)
RUA1 T1 Over a 3ms window, five or fewer 0s are
received.
Over a 3ms window, six or more 0s are
received.
RCL
(Note 1) E1 255 (or 2048) consecutive 0s received
(G.775) (Note 2)
In 255-bit times, at least 32 1s are
received.
RCL
(Note 1) T1 192 (or 1544) consecutive 0s are received
(Note 2)
14 or more 1s out of 112 possible bit
positions are received, starting with the
first 1 received.
Note 1: RCL is also known as a loss of signal (LOS) or Red Alarm in T1.
Note 2: See CCR1.5 for details.
IMR (07H): Interrupt Mask Register
(MSB)
(LSB)
LUP LDN LOTC RUA1 RCL TCLE TOCD PRBSD
NAME POSITION FUNCTION

LUP IMR.7
Loop-Up Code Detected
0 = interrupt masked
1 = interrupt enabled
LDN IMR.6
Loop-Down Code Detected
0 = interrupt masked
1 = interrupt enabled
LOTC IMR.5
Loss-of-Transmit Clock
0 = interrupt masked
1 = interrupt enabled
RUA1 IMR.4
Receive Unframed All Ones
0 = interrupt masked
1 = interrupt enabled
RCL IMR.3
Receive Carrier Loss
0 = interrupt masked
1 = interrupt enabled
TCLE IMR.2
Transmit Current-Limiter Exceeded
0 = interrupt masked
1 = interrupt enabled
TOCD IMR.1
Transmit Open-Circuit Detect
0 = interrupt masked
1 = interrupt enabled
PRBSD IMR.0
PRBS Detection
0 = interrupt masked
1 = interrupt enabled
DS21448 3.3V T1/E1/J1 Quad Line Interface
RIR1 (08H): Receive Information Register 1
(MSB)
(LSB)
ZD 16ZD HBD RCLC RUA1C JALT — —
NAME POSITION FUNCTION

ZD
(Latched) RIR1.7
Zero Detect. This bit is set when a string of at least four (ETS = 0) or eight (ETS = 1)
consecutive 0s (regardless of the length of the string) have been received. This bit is cleared
when read.
16ZD
(latched) RIR1.6 16 Zero Detect. This is set when at least 16 consecutive 0s (regardless of the length of the
string) have been received. This bit is cleared when read.
HBD
(Latched) RIR1.5
HDB3/B8ZS Word Detect. This is set when an HDB3 (ETS = 0) or B8ZS (ETS = 1) codeword
is detected independently of the receive HDB3/B8ZS mode (CCR4.6) being enabled. This bit
is cleared when read. It is useful for automatically setting the line coding.
RCLC
(Latched) RIR1.4 RCL Clear. Set when the RCL alarm has met the clear criteria defined in Table 5-A. This bit
is cleared when read.
RUA1C
(Latched) RIR1.3 Receive Unframed All-Ones Clear. This bit is set when the unframed all-ones signal is no
longer detected. This bit is cleared when read (Table 5-A).
JALT
(Latched) RIR1.2
Jitter Attenuator Limit Trip. This bit is set when the jitter attenuator FIFO reaches within 4 bits
of its useful limit. This bit is cleared when read and is useful for debugging jitter attenuation
operation.
N/A RIR1.1 Not Assigned. Could be any value when read.
N/A RIR1.0 Not Assigned. Could be any value when read.
RIR2 (09H): Receive Information Register 2
(MSB)
(LSB)
RL3 RL2 RL1 RL0 — — ARLB SEC
NAME POSITION FUNCTION

RL3
(Real Time) RIR2.7 Receive Level Bit 3 (Table 5-B)
RL2
(Real Time) RIR2.6 Receive Level Bit 2 (Table 5-B)
RL1
(Real Time) RIR2.5 Receive Level Bit 1 (Table 5-B)
RL0
(Real Time) RIR2.4 Receive Level Bit 0 (Table 5-B)
N/A RIR2.3 Not Assigned. Could be any value when read.
N/A RIR2.2 Not Assigned. Could be any value when read.
ARLB
(Real Time) RIR2.1
Automatic Remote Loopback Detected. This bit is set to 1 when the automatic remote
loopback circuitry has detected the presence of a loop-up code for 5 seconds. It remains set
until the automatic RLB circuitry has detected the loop-down code for 5 seconds. See
Section 11 for more details. This bit is forced low when the automatic RLB circuitry is
disabled (CCR6.5 = 0).
SEC
(Latched) RIR2.0 One-Second Timer. This bit is set to 1 on one-second boundaries as timed by the device,
based on the RCLK. It is cleared when read.
DS21448 3.3V T1/E1/J1 Quad Line Interface
Table 5-B. Receive Level Indication
0 0 0 -20.0 to -22.5 0 0 1 -22.5 to -25.0 0 1 0 -25.0 to -27.5 0 1 1 -27.5 to -30.0 1 0 0 -30.0 to -32.5 1 0 1 -32.5 to -35.0 1 1 0 -35.0 to -37.5 1 1 1 -37.5 to -40.0
RL3 RL2 RL1 RL0 RECEIVE LEVEL (dB)
0 0 0 Greater than -2.5 0 0 1 -2.5 to -5.0 0 1 0 -5.0 to -7.5 0 1 1 -7.5 to -10.0 1 0 0 -10.0 to -12.5 1 0 1 -12.5 to -15.0 1 1 0 -15.0 to -17.5 1 1 1 -17.5 to -20.0
DS21448 3.3V T1/E1/J1 Quad Line Interface
6. DIAGNOSTICS

6.1 In-Band Loop-Code Generation and Detection

The DS21448 can generate and detect a repeating bit pattern from 1 to 8 or 16 bits in length. To transmit a pattern,
the user loads the pattern into the transmit code definition (TCD1 and TCD2) registers and selects the proper
length of the pattern by setting the TC0 and TC1 bits in the in-band code control (IBCC) register. When generating
a 1-, 2-, 4-, 8-, or 16-bit pattern, the transmit code registers (TCD1 and TCD2) must be filled with the proper code.
Generation of a 1-, 3-, 5-, or 7-bit pattern only requires TCD1 to be filled. Once this is accomplished, the pattern is
transmitted, as long as the TLCE control bit (CCR3.3) is enabled. For example, if the user wished to transmit the
standard loop-up code for CSUs, which is a repeating pattern of ...10000100001..., then 80h would be loaded into
TCD1, and the length would set using TC1 and TC0 in the IBCC register to 5 bits.
The DS21448 can detect two separate repeating patterns to allow for a loop-up code and a loop-down code to be
detected. The user programs the codes in the receive-up code definition (RUPCD1 and RUPCD2) registers and the
receive-down code definition (RDNCD1 and RDNCD2) registers; the length of each pattern is selected through the
IBCC register. The DS21448 detects repeating pattern codes with bit-error rates as high as 1 x 10-2. The code
detector has a nominal integration period of 48ms, so after approximately 48ms of receiving either code, the proper
status bit (LUP at SR.7 and LDN at SR.6) is set to 1. Normally codes are sent for a period of 5 seconds. It is
recommended that the software poll the DS21448 every 100ms to 1000ms until 5 seconds has elapsed to ensure
the code is continuously present.
IBCC (0AH): In-Band Code Control Register
(MSB)
(LSB)
TC1 TC0 RUP2 RUP1 RUP0 RDN2 RDN1 RDN0
NAME POSITION FUNCTION

TC1 IBCC.7 Transmit Code Length Definition Bit 1 (Table 6-A)
TC0 IBCC.6 Transmit Code Length Definition Bit 0. (Table 6-A)
RUP2 IBCC.5 Receive Up Code Length Definition Bit 2 (Table 6-B)
RUP1 IBCC.4 Receive-Up Code Length Definition Bit 1 (Table 6-B)
RUP0 IBCC.3 Receive-Up Code Length Definition Bit 0 (Table 6-B)
RDN2 IBCC.2 Receive-Down Code Length Definition Bit 2 (Table 6-B)
RDN1 IBCC.1 Receive-Down Code Length Definition Bit 1 (Table 6-B)
RDN0 IBCC.0 Receive-Down Code Length Definition Bit 0 (Table 6-B) D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0D0
DS21448 3.3V T1/E1/J1 Quad Line Interface
Table 6-A. Transmit Code Length
TC1 TC0 LENGTH SELECTED
(BITS)

0 0 5
0 1 6/3
1 0 7
1 1 16/8/4/2/1
Table 6-B. Receive Code Length
RUP2/RDN2 RUP1/RDN1 RUP0/RDN0 LENGTH SELECTED
(BITS)

0 0 0 1
0 0 1 2
0 1 0 3
0 1 1 4
1 0 0 5
1 0 1 6
1 1 0 7
1 1 1 16/8
TCD1 (0BH): Transmit Code Definition Register 1
(MSB)
(LSB)
C7 C6 C5 C4 C3 C2 C1 C0
NAME POSITION FUNCTION

C7 TCD1.7 Transmit Code Definition Bit 7. First bit of the repeating pattern.
C6 TCD1.6 Transmit Code Definition Bit 6
C5 TCD1.5 Transmit Code Definition Bit 5
C4 TCD1.4 Transmit Code Definition Bit 4
C3 TCD1.3 Transmit Code Definition Bit 3
C2 TCD1.2 Transmit Code Definition Bit 2. A don’t care if a 5-bit length is selected.
C1 TCD1.1 Transmit Code Definition Bit 1. A don’t care if a 5-bit or 6-bit length is selected.
C0 TCD1.0 Transmit Code Definition Bit 0. A don’t care if a 5-, 6-, or 7-bit length is selected.
TCD2 (0CH): Transmit Code Definition Register 2
(MSB)
(LSB)
C15 C14 C13 C12 C11 C10 C9 C8
NAME POSITION FUNCTION

C15 TCD2.7 Transmit Code Definition Bit 15
C14 TCD2.6 Transmit Code Definition Bit 14
C13 TCD2.5 Transmit Code Definition Bit 13
C12 TCD2.4 Transmit Code Definition Bit 12
C11 TCD2.3 Transmit Code Definition Bit 11
C10 TCD2.2 Transmit Code Definition Bit 10
C9 TCD2.1 Transmit Code Definition Bit 9
C8 TCD2.0 Transmit Code Definition Bit 8
DS21448 3.3V T1/E1/J1 Quad Line Interface
RUPCD1 (0DH): Receive-Up Code Definition Register 1
(MSB)
(LSB)
C7 C6 C5 C4 C3 C2 C1 C0
NAME POSITION FUNCTION

C7 RUPCD1.7 Receive-Up Code Definition Bit 7. First bit of the repeating pattern.
C6 RUPCD1.6 Receive-Up Code Definition Bit 6. A don’t care if a 1-bit length is selected.
C5 RUPCD1.5 Receive-Up Code Definition Bit 5. A don’t care if a 1-bit or 2-bit length is selected.
C4 RUPCD1.4 Receive-Up Code Definition Bit 4. A don’t care if a 1-bit to 3-bit length is selected.
C3 RUPCD1.3 Receive-Up Code Definition Bit 3. A don’t care if a 1-bit to 4-bit length is selected.
C2 RUPCD1.2 Receive-Up Code Definition Bit 2. A don’t care if a 1-bit to 5-bit length is selected.
C1 RUPCD1.1 Receive-Up Code Definition Bit 1. A don’t care if a 1-bit to 6-bit length is selected.
C0 RUPCD1.0 Receive-Up Code Definition Bit 0. A don’t care if a 1-bit to 7-bit length is selected.
RUPCD2 (0EH): Receive-Up Code Definition Register 2
(MSB)
(LSB)
C15 C14 C13 C12 C11 C10 C9 C8
NAME POSITION FUNCTION

C15 RUPCD2.7 Receive-Up Code Definition Bit 15
C14 RUPCD2.6 Receive-Up Code Definition Bit 14
C13 RUPCD2.5 Receive-Up Code Definition Bit 13
C12 RUPCD2.4 Receive-Up Code Definition Bit 12
C11 RUPCD2.3 Receive-Up Code Definition Bit 11
C10 RUPCD2.2 Receive-Up Code Definition Bit 10
C9 RUPCD2.1 Receive-Up Code Definition Bit 9
C8 RUPCD2.0 Receive-Up Code Definition Bit 8
RDNCD1 (0FH): Receive-Down Code Definition Register 1
(MSB)
(LSB)
C7 C6 C5 C4 C3 C2 C1 C0
NAME POSITION FUNCTION

C7 RDNCD1.7 Receive-Down Code Definition Bit 7. First bit of the repeating pattern.
C6 RDNCD1.6 Receive-Down Code Definition Bit 6. A don’t care if a 1-bit length is selected.
C5 RDNCD1.5 Receive-Down Code Definition Bit 5. A don’t care if a 1-bit or 2-bit length is selected.
C4 RDNCD1.4 Receive-Down Code Definition Bit 4. A don’t care if a 1-bit to 3-bit length is selected.
C3 RDNCD1.3 Receive-Down Code Definition Bit 3. A don’t care if a 1-bit to 4-bit length is selected.
C2 RDNCD1.2 Receive-Down Code Definition Bit 2. A don’t care if a 1-bit to 5-bit length is selected.
C1 RDNCD1.1 Receive-Down Code Definition Bit 1. A don’t care if a 1-bit to 6-bit length is selected.
C0 RDNCD1.0 Receive-Down Code Definition Bit 0. A don’t care if a 1-bit to 7-bit length is selected.
RDNCD2 (10H): Receive-Down Code Definition Register 2
(MSB)
(LSB)
C15 C14 C13 C12 C11 C10 C9 C8
NAME POSITION FUNCTION

C15 RDNCD2.7 Receive-Down Code Definition Bit 15
C14 RDNCD2.6 Receive-Down Code Definition Bit 14
C13 RDNCD2.5 Receive-Down Code Definition Bit 13
C12 RDNCD2.4 Receive-Down Code Definition Bit 12
C11 RDNCD2.3 Receive-Down Code Definition Bit 11
C10 RDNCD2.2 Receive-Down Code Definition Bit 10
C9 RDNCD2.1 Receive-Down Code Definition Bit 9
C8 RDNCD2.0 Receive-Down Code Definition Bit 8
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