AGERE TA16

Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demultiplexer
Applications
■
Telecommunications:
— Inter- and intraoffice SONET/SDH
— Subscriber loop
— Metropolitan area networks
■
High-speed data communications
Description
The TA16-Type transponders integrate up to 15 discrete ICs
and optical components, including a 2.5 Gbits/s optical transmitter and receiver pair, all in a single, compact package.
Features
■
2.5 Gbits/s optical transmitter and receiver with
16-channel 155 Mbits/s multiplexer/demultiplexer
■
Available with 1.31 µm Fabry-Perot laser transmitter and PIN receiver for intraoffice applications,
and 1.31 µm or 1.55 µm DFB laser transmitters
and PIN or APD receiver for short-haul to long-haul
applications
■
Pigtailed low-profile package
■
Differential LVPECL data interface
■
Operating case temperature range: 0 °C to 65 °C
■
Automatic transmitter optical power control
■
Laser bias monitor output
■
Optical transmitter disable input
■
SONET frame-detect enable
■
Loss of signal, loss of sync, loss of framing alarms
■
Diagnostic loopback capability
■
Line loopback operation
The TA16 transponder performs the parallel-to-serialto-optical transport and optical transport-to-serial-toparallel function of the SONET/SDH protocol. The
TA16 transmitter performs the bit serialization and
optical transmission of SONET/SDH OC-48/STM-16
data that has been formatted into standard SONET/
SDH compliant, 16-bit parallel format. The TA16
receiver performs the optical-to-electrical conversion
function and is then able to detect frame and byte
boundaries and demultiplex the serial data into 16-bit
parallel OC-48/STM-16 format.
Note: The TA16 transponder does not perform bytelevel multiplexing or interleaving.
Figure 1 shows a simplified block diagram of the
TA16-type transponder. This device is a bidirectional
module designed to provide a SONET or SDH compliant electro-optical interface between the SONET/
SDH photonic physical layer and the electrical section layer. The module contains a 2.5 Gbits/s optical
transmitter and a 2.5 Gbits/s optical receiver in the
same physical package along with the electronics
necessary to multiplex and demultiplex sixteen
155 Mbits/s electrical channels. Clock synthesis and
clock recovery circuits are also included within the
module.
In the transmit direction, the transponder module
multiplexes sixteen 155 Mbits/s LVPECL electrical
data signals into an optical signal at 2488.32 Mbits/s
for launching into optical fiber. An internal 2.488 GHz
reference oscillator is phase-locked to an external
155 MHz data timing reference.
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Table of Contents
Contents
Page
Features .................................................................... 1
Applications ............................................................... 1
Description ................................................................ 1
Absolute Maximum Ratings ....................................... 3
Pin Information .......................................................... 5
Pin Descriptions ........................................................ 6
Functional Description ............................................ 12
Receiver ............................................................. 12
Transmitter ......................................................... 12
Loopback Modes ................................................ 13
Transponder Interfacing ...................................... 13
Optical Characteristics ............................................ 14
Electrical Characteristics ......................................... 15
Timing Characteristics ............................................ 17
Transmitter Data Input Timing ............................ 17
Input Timing Mode 1 .......................................... 18
Input Timing Mode 2 .......................................... 19
Forward Clocking ............................................... 20
PCLK-to-PICLK Timing ......................................... 21
PHERR/PHINIT ................................................... 22
Receiver Framing ............................................... 24
Qualification and Reliability ..................................... 26
Laser Safety Information ........................................ 26
Class 1 Laser Product......................................... 26
Electromagnetic Emissions and Immunity .......... 26
Outline Diagram ...................................................... 27
Ordering Information ............................................... 28
Related Product Information .................................... 28
2
Tables
Page
Table 1. TA16-Type Transponder Pinout .................. 6
Table 2. TA16-Type Transponder Input
Pin Descriptions ......................................... 10
Table 3. TA16-Type Transponder Output
Pin Descriptions ......................................... 11
Table 4. OC48/STM-16 Transmitter Optical
Characteristics ........................................... 14
Table 5. OC48/STM-16 Receiver Optical
Characteristics ........................................... 14
Table 6. Transmitter Electrical I/O Characteristics .. 15
Table 7. Receiver Electrical I/O Characteristics ...... 16
Table 8. Power Supply Characteristics ................... 16
Table 9. Transmitter ac Timing Characteristics ....... 23
Table 10. Receiver ac Timing Characteristics ......... 23
Table 11. Ordering Information ................................ 28
Table 12. Related Product Information .................... 28
Figures
Page
Figure 1. TA16-Type Transponder Block Diagram .... 4
Figure 2. TA16-Type Transponder Pinout ................. 5
Figure 3. Transponder Interfacing............................ 13
Figure 4. Block Diagram Timing Mode 1.................. 18
Figure 5. Block Diagram Timing Mode 2.................. 19
Figure 6. Forward Clocking of TA16 Transmitter.....20
Figure 7. PCLK-to-PICLK Timing...............................21
Figure 8. PHERR/PHINIT Timing.............................22
Figure 9. ac Input Timing .........................................22
Figure 10. Receiver Output Timing Diagram ...........23
Figure 11. Frame and Byte Detection ......................24
Figure 12. OOF Timing (FRAMEN = High) ..............24
Figure 13. FRAMEN Timing .....................................25
Figure 14. Interfacing to TxREFCLK Input................. 25
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Description (continued)
In the receive direction, the transponder module
receives a 2488.32 Mbits/s optical signal and converts
it to an electrical signal, extracts a clock signal, and
then demultiplexes the data into sixteen 155 Mbits/s
differential LVPECL data signals. The optical receiver is
available with either a PIN photodetector or with an
APD photodetector. The receiver operates over the
wavelength range of 1.1 µm to 1.6 µm and is fully compliant to SONET/SDH OC-48/STM-16 physical layer
specifications as shown in Table 5, Optical Characteristics.
The optical transmitter is available with either a 1.31 µm
Fabry-Perot laser for short-reach applications or
1.31 µm and 1.55 µm DFB lasers for intermediate- to
long-reach applications. The optical output signal is
SONET and ITU compliant for OC-48/STM-16 applications as shown in Table 4, Optical Characteristics.
Absolute Maximum Ratings
Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. These are absolute stress ratings only. Functional operation of the device is not implied at these or any other conditions in excess
of those given in the operations sections of the data sheet. Exposure to absolute maximum ratings for extended
periods can adversely affect reliability.
Parameter
Symbol
Min
Max
Unit
Operating Case Temperature Range
TC
0
75
°C
Storage Case Temperature Range
TS
–40
85
°C
Supply Voltage
—
–0.5
5.5
V
Voltage on Any LVPECL Pin
—
0
VCC
—
High-speed LVPECL Output Source Current
—
—
50
mA
Voltage1
ESD
—
500
V
Relative Humidity (noncondensing)
RH
—
85
%
Receiver Optical Input Power—Biased:
APD
PIN
PIN
PIN
—
—
0
8
dBm
dBm
Minimum Fiber Bend Radius
—
1.25 (31.8)
—
in. (mm)
Static Discharge
1. Human body model.
Agere Systems Inc.
3
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Block Diagram
TXDIS
LSRBIAS
LSR ALRM
LPM
PICLKP/N
16
TXREFCLKP/N
D
OC-48/STM-16
OPTICAL TRANSMITTER
2
TIMING
GENERATION
PHINIT
PHERR
PCLKP/N
16:1 PARALLEL
TO SERIAL
2
2
LOCKDET
MUX
TXD[0:15]N
16
MUX
TXD[0:15]P
CLOCK DIVIDER
AND
PHASE DETECT
LLOOP
RESET
DLOOP
OOF
FRAMEN
SEARCH
FP
POCLKP/N
2
MUX
FRAME/BYTE
DETECT
TIMING
GEN
CK
RXQ[0:15]N
16
16
1:16 SERIAL
TO PARALLEL
MUX
RXQ[0:15]P
D
OC-48/STM-16
OPTICAL RECEIVER
W/CLOCK RECOVERY
LOS
IPDMON
1-1011(F).e
Figure 1. TA16-Type Transponder Block Diagram
4
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Pin Information
80
70
60
50
40
30
20
10
1
FGND
NC
NC
NC
NC
RXDGND
RXQ00N
RXQ00P
RXQ02N
RXQ02P
RXDGND
RXQ04N
RXQ04P
RXQ06N
RXQ06P
RXDGND
RXQ08N
RXQ08P
RXQ10N
RXQ10P
RXDGND
RXQ12N
RXQ12P
RXQ14N
RXQ14P
RXDGND
NC
NC
NC
RXDGND
RXAGND
RXAGND
RX3.3A
RXAGND
RXAGND
NC
RX3.3D
RX3.3D
RXDGND
FRAMEN
FP
NC
DLOOP
NC
LSRBIAS
LSRALM
LPM
TXAGND
TX3.3A
TX3.3A
TXAGND
TX3.3D
TX3.3D
TXDGND
LOCKDET
PICLKN
PICLKP
TXDGND
TXD01N
TXD01P
TXD03N
TXD03P
TXDGND
TXD05N
TXD05P
TXD07N
TXD07P
TXDGND
TXD09N
TXD09P
TXD11N
TXD11P
TXDGND
TXD13N
TXD13P
TXD15N
TXD15P
TXDGND
IPDMON
FGND
FGND
NC
NC
NC
NC
RXDGND
RXQ01N
RXQ01P
RXQ03N
RXQ03P
RXDGND
RXQ05N
RXQ05P
RXQ07N
RXQ07P
RXDGND
RXQ09N
RXQ09P
RXQ11N
RXQ11P
RXDGND
RXQ13N
RXQ13P
RXQ15N
RXQ15P
RXDGND
NC
NC
NC
NC
POCLKN
POCLKP
RX3.3A
RXAGND
RXAGND
SEARCH
RX3.3D
RX3.3D
RXDGND
OOF
RXDGND
LOS
LLOOP
PHERR
NC
TXDIS
PHINIT
NC
TX3.3A
TX3.3D
TXAGND
TXDGND
PCLKN
PCLKP
TXDGND
TXD00N
TXD00P
TXDGND
TXD02N
TXD02P
TXD04N
TXD04P
TXDGND
TXD06N
TXD06P
TXD08N
TXD08P
TXDGND
TXD10N
TXD10P
TXD12N
TXD12P
TXDGND
TXD14N
TXD14P
TXREFCLKN
TXREFCLKP
TXDGND
RESET
FGND
160
150
RX
140
130
120
110
100
TX
90
TOP VIEW
81
1-1014(F).r2
Figure 2. TA16-Type Transponder Pinout
Agere Systems Inc.
5
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Pin Descriptions
Table 1. TA16-Type Transponder Pinout
Pin #
01
02
03
04
05
06
07
08
09
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
Pin Name
FGND
IPDMON
TxDGND
TxD15P
TxD15N
TxD13P
TxD13N
TxDGND
TxD11P
TxD11N
TxD09P
TxD09N
TxDGND
TxD07P
TxD07N
TxD05P
TxD05N
TxDGND
TxD03P
TxD03N
TxD01P
TxD01N
TxDGND
PIC LKP
PICLKN
LOCKDET
TxDGND
Tx3.3D
Tx3.3D
TxAGND
Tx3.3A
Tx3.3A
TxAGND
LPM
LSRALRM
LSRBIAS
NC
DLOOP
NC
FP
FRAMEN
RxDGND
I/O
I
O
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
O
I
I
I
I
I
I
I
O
O
O
—
I
—
O
I
I
Logic
Supply
Analog
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVTTL
Supply
Supply
Supply
Supply
Supply
Supply
Supply
Analog
Analog
Analog
—
LVTTL
—
LVPECL
LVTTL
Supply
Description
Ground1
Frame
Receiver Photodiode Current Monitor
Transmitter Digital Ground
Transmitter 155 Mbits/s MSB Data Input
Transmitter 155 Mbits/s MSB Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Byte-Aligned Parallel Input Clock at 155 MHz
Byte-Aligned Parallel Input Clock ar 155 MHz
Lock Detect
Transmitter Digital Ground
Transmitter 3.3 V Digital Supply
Transmitter 3.3 V Digital Supply
Transmitter Analog Ground
Transmitter 3.3 V Analog Supply
Transmitter 3.3 V Analog Supply
Transmitter Analog Ground
Laser Power Monitor
Laser Degrade Alarm
Transmitter Laser Bias Output
No User Connection Permitted
Diagnostic Loopback
No User Connection Permitted
Frame Pulse
Frame Enable
Receiver Digital Ground
1. Frame ground is connected to the housing and is isolated from all circuit grounds (TxDGND, TxAGND, RxDGND, RxAGND).
6
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Pin Descriptions (continued)
Table 1. TA16-Type Transponder Pinout (continued)
Pin #
Pin Name
I/O
Logic
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
Rx3.3D
Rx3.3D
NC
RxAGND
RxAGND
Rx3.3A
RxAGND
RxAGND
RxDGND
NC
NC
NC
RxDGND
RxQ14P
RxQ14N
RxQ12P
RxQ12N
RxDGND
RxQ10P
RxQ10N
RxQ08P
RxQ08N
RxDGND
RxQ06P
RxQ06N
RxQ04P
RxQ04N
RxDGND
RxQ02P
RxQ02N
RxQ00P
RxQ00N
RxDGND
NC
NC
NC
NC
FGND
FGND
RESET
TxDGND
TxREFC LKP
TxR EFCLKN
I
I
—
I
I
I
I
I
I
—
—
—
I
O
O
O
O
I
O
O
O
O
I
O
O
O
O
I
O
O
O
O
I
—
—
—
—
I
I
I
I
I
I
Supply
Supply
—
Supply
Supply
Supply
Supply
Supply
Supply
—
—
—
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
—
—
—
—
Supply
Supply
LVTTL
Supply
LVPECL
LVPECL
Description
Receiver 3.3 V Digital Supply
Receiver 3.3 V Digital Supply
No User Connection Permitted
Receiver Analog Ground
Receiver Analog Ground
Receiver 3.3 V Analog Supply
Receiver Analog Ground
Receiver Analog Ground
Receiver Digital Ground
No User Connection Permitted
No User Connection Permitted
No User Connection Permitted
Receiver Digital Ground
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver Digital Ground
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver Digital Ground
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver Digital Ground
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s LSB Data Output
Receiver 155 Mbits/s LSB Data Output
Receiver Digital Ground
No User Connection Permitted
No User Connection Permitted
No User Connection Permitted
No User Connection Permitted
Frame Ground1
Frame Ground1
Master Reset
Transmitter Digital Ground
Transmitter 155 Mbits/s Reference Clock Input
Transmitter 155 Mbits/s Reference Clock Input
1. Frame ground is connected to the housing and is isolated from all circuit grounds (TxDGND, TxAGND, RxDGND, RxAGND).
Agere Systems Inc.
7
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Pin Descriptions (continued)
Table 1. TA16-Type Transponder Pinout (continued)
Pin #
Pin Name
I/O
Logic
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
TxD14P
TxD14N
TxDGND
TxD12P
TxD12N
TxD10P
TxD10N
TxDGND
TxD08P
TxD08N
TxD06P
TxD06N
TxDGND
TxD04P
TxD04N
TxD02P
TxD02N
TxDGND
TxD00P
TxD00N
TxDGND
PCLKP
PC LKN
TxDGND
TxAGND
Tx3.3D
Tx3.3A
NC
PHINIT
TXDIS
NC
PHERR
LLOOP
LOS
RxDGND
OOF
RxDGND
Rx3.3D
Rx3.3D
SEARCH
RxAGND
RxAGND
Rx3.3A
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
O
O
I
I
I
I
—
I
I
—
O
I
O
I
I
I
I
I
O
I
I
I
LVPECL
LVPECL
SUPPLY
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
Supply
LVPECL
LVPECL
Supply
Supply
Supply
Supply
—
LVPECL
TTL
—
LVPECL
LVTTL
LVTTL
Supply
LVTTL
Supply
Supply
Supply
LVTTL
Supply
Supply
Supply
Description
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter 155 Mbits/s Data Input
Transmitter Digital Ground
Transmitter 155 Mbits/s LSB Data Input
Transmitter 155 Mbits/s LSB Data Input
Transmitter Digital Ground
Transmitter Parallel Reference Clock Output
Transmitter Parallel Reference Clock Output
Transmitter Digital Ground
Transmitter Analog Ground
Transmitter Digital 3.3 V Supply
Transmitter Analog 3.3 V Supply
No User Connection Permitted
Phase Initialization
Transmitter Disable
No User Connection Permitted
Phase Error
Line Loopback (active-low)
Loss of Signal
Receiver Digital Ground
Out of Frame (enable frame detection)
Receiver Digital Ground
Receiver Digital 3.3 V Supply
Receiver Digital 3.3 V Supply
Frame Search Output
Receiver Analog Ground
Receiver Analog Ground
Receiver Analog 3.3 V Supply
1. Frame ground is connected to the housing and is isolated from all circuit grounds (TxDGND, TxAGND, RxDGND, RxAGND).
8
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Pin Descriptions (continued)
Table 1. TA16-Type Transponder Pinout (continued)
Pin #
Pin Name
I/O
Logic
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
POCLKP
POCLKN
NC
NC
NC
NC
RxDGND
RxQ15P
RxQ15N
RxQ13P
RxQ13N
RxDGND
RxQ11P
RxQ11N
RxQ09P
RxQ09N
RxDGND
RxQ07P
RxQ07N
RxQ05P
RxQ05N
RxDGND
RxQ03P
RxQ03N
RxQ01P
RxQ01N
RxDGND
NC
NC
NC
NC
FGND
O
O
—
—
—
—
I
O
O
O
O
I
O
O
O
O
I
O
O
O
O
I
O
O
O
O
I
—
—
—
—
I
LVPECL
LVPECL
—
—
—
—
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
LVPECL
LVPECL
LVPECL
LVPECL
Supply
—
—
—
—
Supply
Description
Byte-Aligned Parallel Output Clock at 155 MHz
Byte-Aligned Parallel Output Clock at 155 MHz
No User Connection Permitted
No User Connection Permitted
No User Connection Permitted
No User Connection Permitted
Receiver Digital Ground
Receiver MSB 155 Mbits/s Data Output
Receiver MSB 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver Digital Ground
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver Digital Ground
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver Digital Ground
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver 155 Mbits/s Data Output
Receiver Digital Ground
No User Connection Permitted
No User Connection Permitted
No User Connection Permitted
No User Connection Permitted
Frame Ground1
1. Frame ground is connected to the housing and is isolated from all circuit grounds (TxDGND, TxAGND, RxDGND, RxAGND).
Agere Systems Inc.
9
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Pin Descriptions (continued)
Table 2. TA16-Type Transponder Input Pin Descriptions
Pin Name
Pin Description
TxD[0:15]P
TxD[0:15]N
16-bit Differential LVPECL Parallel Input Data Bus. TxD15P/N is the most significant bit of the input word and is the first bit serialized. TxD00P/N is the least significant bit of the input word and is the last bit serialized. TxD[0:15]P/N is sampled on
the rising edge of PIC LK.
PICLKP
Differential LVPECL Parallel Input Clock. A 155 MHz nominally 50% duty cycle
PICLKN
input clock to which TxD[0:15]P/N is aligned. The rising edge of PICLK transfers the
data on the 16 TxD inputs into the holding register of the parallel-to-serial converter.
TxREFCLKP Differential LVPECL Low Jitter 155.520 MHz Input Reference Clock. This input is
TxREFCLKN used as the reference for the internal clock frequency synthesizer which generates
the 2.5 GHz bit rate clock used to shift data out of the parallel-to-serial converter and
also for the byte-rate clock, which transfers the 16-bit parallel input data from the
input holding register into the parallel-to-serial shift register. Input is internally terminated and biased. See discussion on interfacing, page 13.
TxDIS
Transmitter Disable Input. A logic HIGH on this input pin shuts off the transmitter’s
laser so that there is no optical output.
DLOOP
Diagnostic Loopback Enable (LVTTL). When the DLOOP input is low, the
2.5 Gbits/s serial data stream from the parallel-to-serial converter is looped back
internally to the serial-to-parallel converter along with an internally generated bit synchronous serial clock. The received serial data path from the optical receiver is disabled.
LLOOP
Line Loopback Enable (LVTTL). When LLOOP is low, the 2.5 Gbits/s serial data and
recovered clock from the optical receiver are looped directly back to the optical transmitter. The multiplexed serial data from the parallel-to-serial converter is ignored.
PHINIT
Phase Initialization (LVPECL). A rising edge on this input will realign the internal
timing associated with clocking data into and out of the internal FIFO. For a detailed
explanation, see the section on Transmitter Data Input Timing on page 17.
FRAMEN Frame Enable Input (LVTTL). Enables the frame detection circuitry to detect A1
A2 byte alignment and to lock to a word boundary. The TA16 transponder will continually perform frame acquisition as long as FRAMEN is held high. When this input is
low, the frame-detection circuitry is disabled. Frame-detection process is initiated by
rising edge of out-of-frame pulse.
OOF
Out of Frame (LVTTL). This input indicator is typically generated by external
SONET/SDH overhead monitor circuitry in response to a state in which the frame
boundaries of the received SONET/SDH signal are unknown, i.e., after system reset
or loss of synchronization. The rising edge of the OOF input initiates the frame detection function if FRAMEN is high. The FP output goes high when the frame boundary
is detected in the incoming serial data stream from the optical receiver.
RESET
Master Reset (LVTTL). Reset input for the multiplexer/demultiplexer. A low on this
input clears all buffers and registers. During reset, POCLK and PC LK do not toggle.
10
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Pin Descriptions (continued)
Table 3. TA16-Type Transponder Output Pin Descriptions
Pin Name
Pin Description
RxQ[0:15]P 16-bit Differential LVPECL Parallel Output Data Bus. RxQ[0:15] is the
RxQ[0:15]N 155 Mbyte/s 16-bit output word. RxQ15P/N is the most significant bit of the received
word and is the first bit serialized. RxQ00P/N is the least significant bit of the
received word and is the last bit serialized. RxQ[0:15]P/N is updated on the falling
edge of POCLk.
POCLKP
Differential LVPECL Parallel Output Clock. A 155 MHz nominally 50% duty cycle,
POCLKN
byte rate output clock that is aligned to the RxQ[0:15] byte serial output data.
RxQ[0:15] and FP are updated on the falling edge of POCLK.
FP
Frame Pulse (LVPECL). Indicates frame boundaries in the received serial data
stream. If framing pattern detection is enabled (FRAMEN high and OOF), FP pulses
high for one POC LK cycle when a 32-bit sequence matching the framing pattern is
detected in the received serial data. FP is updated on the falling edge of POC LK.
SEARCH A1 A2 Frame Search Output (LVTTL). A high on this output pin indicates that the
frame detection circuit is active and is searching for a new A1 A2 byte alignment.
This output will be high during the entire A1 A2 frame search. Once a new alignment
is found, this signal will remain high for a minimum of one 155 MHz clock period
beyond the third A2 byte before it will be set low.
LOS
Loss of Signal (LVTTL). A low on this output indicates a loss of lock by the clock
recovery circuit in the optical receiver.
LSRBIAS Laser Bias (Analog). Provides an indication of the health of the laser in the transmitter. This output changes at the rate of 20 mV/mA of bias current. If this output
voltage reaches 1.4 V (70 mA of bias), the automatic power control circuit is struggling to maintain output power. This may indicate that the transmitter has reached an
end-of-life condition.
LSRALRM Laser Degrade Alarm (5 V CMOS). A logic low on this output indicates that the
transmitter’s automatic power control circuits are unable to maintain the nominal output power. This output becomes active when the optical output power degrades 2 dB
below the nominal operating power.
LPM
Laser Power Monitor (Analog). Provides an indication of the output power level
from the transmitter laser. This output is set at 500 mV for the nominal transmitter
optical output power. If the optical power decreases by 3 dB, this output will drop to
approximately 250 mV, and if the output power should increase by 3 dB, this output
will increase to 1000 mV.
PCLKP/N Parallel Byte Clock (Differential LVPECL). A byte-rate reference clock generated
by dividing the internal 2.488 GHz serial bit clock by 16. This output is normally used
to synchronize byte-wide transfers from upstream logic into the TA16 transponder.
See timing discussion for additional details, page 17.
PHERR
Phase Error Signal (Single-Ended LVPECL). This signal pulses high during each
PC LK cycle for which there is potential setup/hold timing violations between the internal byte clock and the PICLK timing domains. PHERR is updated on the falling edge
of the PICLK output. For a detailed explanation, see the section on Transmitter Data
Input Timing on page 17.
IDPMON
Receiver Photodiode Current Monitor (Analog). This output provides a current
output that is a mirror of the photocurrent generated by the optical receiver’s photodiode (APD or PIN).
LOCKDET Lock Detect (LVTTL). This output goes low after the transmit side PLL has locked to
the clock signal provided at the TXREFCLK input pins. LOCKDET is an asynchronous
output.
Agere Systems Inc.
11
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Functional Description
Receiver
The optical receiver in the TA16-type transponder is
optimized for the particular SDH/SONET application
segment in which it was designed to operate and will
have either an APD or PIN photodetector. The detected
serial data output of the optical receiver is connected to
a clock and data recovery circuit (CDR), which extracts
a 2488.32 MHz clock signal. This recovered serial bit
clock signal and a retimed serial data signal are presented to the 16-bit serial-to-parallel converter and to
the frame and byte detection logic.
The serial-to-parallel converter consists of three 16-bit
registers. The first is a serial-in parallel-out shift register, which performs serial-to-parallel conversion. The
second is an internal 16-bit holding register, which
transfers data from the serial-to-parallel register on
byte boundaries as determined by the frame and byte
detection logic. On the falling edge of the free-running
POCLK signal, the data in the holding register is transferred to the output holding register where it becomes
available as RxQ[0:15].
The frame and byte boundary detection circuitry
searches the incoming data for three consecutive A1
bytes followed immediately by an A2 byte. Framing pattern detection is enabled and disabled by the FRAMEN
input. The frame detection process is started by a rising edge on OOF while FRAMEN is active (FRAMEN=
high). It is disabled when a framing pattern is detected.
When framing pattern detection is enabled (FRAMEN =
high), the framing pattern is used to locate byte and
frame boundaries in the incoming serial data stream
from the CDR circuits. During this time, the parallel output data bus (RxQ[0:15]) will not contain valid data.
The timing generator circuitry takes the located byte
boundary and uses it to block the incoming serial data
stream into bytes for output on the parallel output data
bus (RxQ[0:15]). The frame boundary is reported on
the framing pulse (FP) output when any 32-bit pattern
matching the framing pattern is detected in the incoming serial data stream. When framing detection is disabled (FRAMEN = low), the byte boundary is fixed at
the location found when frame detection was previously
enabled.
Transmitter
Data Sheet
March 2001
element and can operate at either 1310 nm or
1550 nm. The transmitter is driven by a serial data
stream developed in the parallel-to-serial conversion
logic and by a 2488.32 MHz serial bit clock signal synthesized from the 155.52 MHz TxREFCLK input.
The parallel-to-serial converter block shown in Figure 1
is comprised of two byte-wide registers. The first register latches the 16 bits of parallel input data (TxD[0:15])
on the rising edge of PIC LK. The second register is a
16-bit parallel-load serial-out shift register that is
loaded from the input register. An internally generated
byte clock, which is phase aligned to the 2488.32 MHz
serial transmit clock, activates the data transfer
between the input register and the parallel-to-serial
register.
The clock divider and phase detect circuitry shown in
Figure 1 generates internal reference clocks and timing
functions for the transmitter. Therefore, it is important
that the TxREFCLK input is generated from a precise
and stable source. To prevent internal timing signals
from producing jitter in the transmitted serial data that
exceeds the SDH/SONET jitter generation requirements of 0.01 UI, it is required that the TxREFCLK input
be generated from a crystal oscillator or other source
having a frequency accuracy better than 20 ppm. In
order to meet the SDH/SONET requirement, the reference clock jitter must be guaranteed to be less than
1 ps rms over the 12 kHz to 20 MHz bandwidth. When
used in SONET network applications, this input clock
must be derived from a source that is synchronized to
the primary reference clock (stratum 1 clock).
The timing generation circuitry provides two separate
functions. It develops a byte rate clock that is synchronized to the 2488.32 MHz transmit serial clock, and it
provides a mechanism for aligning the phase between
the incoming byte clock (PICLK) and the clock which
loads the parallel data from the input register into the
parallel-to-serial shift register. The PCLK output is a
byte rate (155 MHz) version of the serial transmit clock
and is intended for use by upstream multiplexing and
overhead processing circuits. Using PCLK for upstream
circuits will ensure a stable frequency and phase relationship between the parallel data coming into the
transmitter and the subsequent parallel-to-serial timing
functions. The timing generator also provides a feedback reference clock to the phase detector for use by
the transmit serial clock synthesizer (for additional discussions, see transmitter input options, page 17.)
The optical transmitter in the TA16-type transponder is
optimized for the particular SDH/SONET segment in
which it is designed to operate. The transmitter will
have either a Fabry-Perot or a DFB laser as the optical
12
12
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Functional Description (continued)
Transponder Interfacing
Loopback Modes
The TxD[0:15]P/N and PICLKP/N inputs and the
RxQ[0:15]P/N, POCLKP/N, and PCLKP/N outputs are
high-speed (155 Mbits/s), LVPECL differential data and
clock signals. To maintain optimum signal fidelity, these
inputs and outputs must be connected to their terminating devices via 50 Ω controlled-impedance transmission lines. The transmitter inputs (TxD[0:15]P/N,
TxREFCLKP/N, and PIC LKP/N) must be terminated as
close as possible to the TA16 transponder connector
with a Thevenin equivalent impedance equal to 50 ¾
terminated to Vcc – 2V. The receiver outputs
(RxQ[0:15]P/N, POCLKP/N, and PCLKP/N) must be terminated as close as possible to the device (IC) that
these signals interface to with a Thevenin equivalent
impedance equal to 50 Ω terminated to Vcc – 2 V.
The TA16 transponder is capable of operating in either
of two loopback modes: diagnostic loopback or line
loopback.
Line Loopback
When LLOOP is pulled low, the received serial data
stream and recovered 2488.32 MHz serial clock from
the optical receiver are connected directly to the serial
data and clock inputs of the optical transmitter. This
establishes a receive-to-transmit loopback at the serial
line rate.
Diagnostic Loopback
When DLOOP is pulled low, a loopback path is established from the transmitter to the receiver. In this mode,
the serial data from the parallel-to-serial converter and
the transmit serial clock are looped back to the serialto-parallel converter and the frame and byte detect circuitry, respectively.
Figure 3, below, shows one example of the proper terminations. Other methods may be used, provided they
meet the requirements stated above.
TxREFCLKP/N. The reference clock input is different
than the TxD and PICLK inputs because it is internally
terminated, ac-coupled, and self-biased. Therefore, it
must be treated somewhat differently than the TxD and
PICLK inputs. Figure 14 shows the proper method for
connecting the TxREFCLK input.
3.3 V
SONET/SDH
INTERFACE IC
TA16-TYPE TRANSPONDER
130 Ω
130 Ω
TxD[0:15]P
(LVPECL)
50 Ω IMPEDANCE
TRANSMISSION LINES
80 Ω
3.3 V
130 Ω
80 Ω
130 Ω
80 Ω
80 Ω
Tx
DEMUX
Rx
RxD[0:15]P
(LVPECL)
50 Ω IMPEDANCE
TRANSMISSION LINES
RxLINE
MUX
TxD[0:15]N
(LVPECL)
CONNECTOR
TxLINE
RxD[0:15]N
(LVPECL)
1-1054(F)
Figure 3. Transponder Interfacing
Agere Systems Inc.
13
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Optical Characteristics
Minimum and maximum values specified over operating case temperature range at 50% duty cycle data signal.
Typical values are measured at room temperature unless otherwise noted.
Table 4. OC48/STM-16 Transmitter Optical Characteristics (Tc = 0 °C to 65 °C)
Parameter
Symbol
Min
Typ
Max
Unit
Po
Po
–10
–5
–5
–2
–3
0
dBm
dBm
Po
Po
–2
–2
0
0
2
3
dBm
dBm
λ
λ
λ
λ
1270
1270
1280
1500
—
—
—
—
1360
1360
1335
1580
nm
nm
nm
nm
Spectral Width:
Intraoffice (F-P laser)
Short Haul and Long Haul (DFB laser) 2
∆λrms
∆λ20
—
—
—
—
4
1
nm
nm
Side-mode Suppression Ratio (DFB laser) 3
1
Average Output Power:
Intraoffice (F-P laser)
Short Haul (DFB laser)
Long Haul:
1.3 µm DFB Laser
1.55 µm DFB Laser
Operating Wavelength:
Intraoffice (F-P laser)
Short Haul (DFB laser)
Long Haul (1.3 µm DFB laser)
Long Haul (1.55 µm DFB laser)
SSR
30
—
—
dB
Ratio4
re
8.2
—
—
dB
Optical Rise and Fall Times
tR, tF
—
—
200
ps
Extinction
Eye Mask of Optical Output 5, 6
Compliant with GR-253 and ITU-T G.957
Jitter Generation
Compliant with GR-253 and ITU-T G.958
1. Output power definitions and measurements per ITU-T Recommendation G.957.
2. Full spectral width measured 20 dB down from the central wavelength peak under fully modulated conditions.
3. Ratio of the average output power in the dominant longitudinal mode to the power in the most significant side mode under fully modulated
conditions.
4. Ratio of logic 1 output power to logic 0 output power under fully modulated conditions.
5. GR-253-CORE, Synchronous Optical Network (SONET) Transport Systems: Common Generic Criteria.
6. ITU-T Recommendation G.957, Optical Interfaces for Equipment and Systems Relating to the Synchronous Digital Hierarchy.
Table 5. OC48/STM-16 Receiver Optical Characteristics (Tc = 0 °C to 65 °C)
Parameter
Symbol
Min
Typ
Max
Unit
PRMIN
PRMIN
–20
–29
–25
–34
—
—
dBm
dBm
PRMAX
1
–6
—
—
—
RMAX
—
dBm
dBm
LSTD
LSTD
—
—
TBD
TBD
—
—
dBm
dBm
1
Average Receiver Sensitivity :
PIN Receiver (intraoffice, short haul)
APD Receiver (long haul)
Maximum Optical Power:
PIN Receiver
APD Receiver (long reach)
Link Status Switching Threshold
Decreasing Light Input:
APD
PIN
Link Status Response Time
—
3
—
100
µs
Optical Path Penalty (1310 nm/1550 nm)
—
—
—
1/2
dB
Receiver Reflectance
—
—
—
–27
dB
Jitter Tolerance and JitterTransfer
1. At 1310 nm, 1 x 10
14
–10
BER, 2
23
Compliant with GR-253 and ITU-T G.958
– 1 pseudorandom data input.
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Electrical Characteristics
Table 6. Transmitter Electrical I/O Characteristics (TC = 0 °C to 65 °C, VCC = 3.3 V ± 5%)
Parameter
Symbol
Logic
Min
Typ
Max
Unit
PIC LKP/N
Diff.
LVPECL
153.90
155.52
157.00
MHz
—
—
40
—
60
%
TxR EFCLKP/N
Diff.
LVPECL
–20
—
20
ppm
Reference Clock Jitter
(in 12 KHz to 20 MHz band)
—
—
—
—
1
ps
rms
Reference Clock
Input Duty Cycle
—
—
45
—
55
%
Reference Clock Rise
and Fall Times1
—
—
—
—
1.5
ns
300
150
80
—
—
100
1200
600
120
mV
mV
Ω
VCC – 1.2
VCC – 2.0
300
—
—
—
VCC – 0.3
VCC – 1.5
—
V
V
mV
Parallel Input Clock
Parallel Clock in Duty Cycle
Reference Clock
Frequency Tolerance
Reference Clock Signal Levels:2
Diff. Input Voltage Swing
Single-ended Input Voltage Swing
Differential Input Resistance
Input Data Signal Levels:
Input High, V IH
Input Low, V IL
Input Voltage Swing, ∆VIN
∆VINDIFF
∆VINSINGLE
RDIFF
TxD[0:15]P/N
Diff.
LVPECL
Diff.
LVPECL
Transmitter Disable Input3
TxDIS
TTL (5 V)
2.0
—
5.5
V
Transmitter Enable Input3
TxEN
TTL (5 V)
0
—
0.8
V
LSRBIAS
Analog
0
200
1600
mV
LPM
Analog
35
500
1000
mV
LSRALM
5V
CMOS
4.5
0
—
—
5.2
0.4
V
V
SingleEnded
LVPECL
VCC – 1.0
VCC – 2.3
—
—
VCC – 0.57
VCC – 1.44
V
V
SingleEnded
LVPECL
VCC – 1.2
VCC – 2.2
—
—
VCC – 0.65
VCC – 1.5
V
V
2.0
0
—
—
VCC + 1.0
0.8
V
V
Laser Bias Voltage Output4
Laser Power Monitor
Output5
Laser Degrade Alarm:
Output High, VOH
Output Low, VOL
Phase Initialization:
Input High, V IH
Input Low, V IL
PHINIT
Phase Error6:
Output High, VOH
Output Low, VOL
PHERR
Line Loopback Enable:
Active-Low:
Input High, V IH
Input Low, V IL
1.
2.
3.
4.
5.
6.
LLOOP
LVTTL
20% to 80%.
Internally biased and ac-coupled. See Figure 13.
The transmitter is normally enabled and only requires an external voltage to disable.
Output conversion factor is 20 mV/mA of laser bias current.
Set at 500 mV at nominal output power; will track PO linearly (–3 dB = 250 mV, +3 dB = 1000 mV).
Terminated into 220 Ω to GND with 100 Ω line-to-line.
Agere Systems Inc.
15
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Electrical Characteristics (continued)
Table 6. Transmitter Electrical I/O Characteristics (TC = 0 °C to 65 °C, V CC = 3.3 V ± 5%) (continued)
DLOOP
Diagnostic Loopback Enable:
Active-Low:
Input High, VIH
Input Low, VIL
Parallel Output Clock:6
Output High, VOH
Output Low, VOL
S-E Output Voltage Swing, ∆VSINGLE
Diff. Voltage Swing, ∆VDIFF
1.
2.
3.
4.
5.
6.
LVTTL
PC LKP/N
Diff.
LVPECL
2.0
0
—
—
VCC + 1.0
0.8
V
V
VCC – 1.15
VCC – 1.95
400
800
—
—
—
—
VCC – 0.6
VCC – 1.45
950
1900
V
V
mV
mV
20% to 80%.
Internally biased and ac-coupled. See Figure 13.
The transmitter is normally enabled and only requires an external voltage to disable.
Output conversion factor is 20 mV/mA of laser bias current.
Set at 500 mV at nominal output power; will track PO linearly (–3 dB = 250 mV, +3 dB = 1000 mV).
Terminated into 220 Ω to GND with 100 Ω line-to-line.
Table 7. Receiver Electrical I/O Characteristics (Tc = 0 °C to 65 °C, Vcc = 3.3 V ± 5%)
Parameter
Symbol
Parallel Output Clock:
Output High, VOH
Output Low, VOL
Logic
Min
Typ
Max
Unit
Diff.
LVPECL
VCC – 1.3
VCC – 2.00
—
—
VCC – 0.7
VCC – 1.4
V
V
—
—
40
—
60
%
RxQ[0:15]P/N
Diff.
LVPECL
2.275
1.490
—
—
2.420
1.680
V
V
—
—
1.0
ns
VCC – 1.3
VCC – 2.00
—
—
VCC – 0.7
VCC – 1.4
V
V
2.4
0
—
—
VCC
0.4
V
V
2.00
0.0
—
—
VCC + 1.0
0.8
V
V
2.00
0.0
—
—
VCC + 1.0
0.8
V
V
POCLKP/N
POCLk Duty Cycle
1
Output Data Signal Levels :
Output High, VOH
Output Low, VOL
RxQ[0:15] Rise/Fall Time2
—
—
Frame Pulse:
Output High, VOH
Output Low, VOL
FP
LVPECL
Loss-of-Signal Output:
Output High, VOH
Output Low, VOL
LOS
LVTTL
Out-of-Frame Input:
Input High, VIH
Input Low, VIL
OOF
Frame Enable Input
FRAMEN
LVTTL
LVTTL
1. Terminated into 330 Ω to ground.
2. 20% to 80%, 330 Ω to ground.
Table 8. Power Supply Characteristics (Tc = 0 °C to 65 °C)
Parameter
Supply Voltage
dc Power Supply Current Drain1
Power Dissipation
Symbol
Min
Typ
Max
Unit
VCC
ICC
PDISS
3.13
—
—
3.3
1800
6
3.47
2300
—
V
mA
W
1. Does not include output termination resistor current drain.
16
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Timing Characteristics
Transmitter Data Input Timing
The TA16 transponder utilizes a unique FIFO to decouple the internal and external (PIC LK) clocks. The FIFO
can be initialized, which allows the system designer to
have an infinite PCLK-to-PICLK delay through this interfacing logic (ASIC or commercial chip set). The configuration of the FIFO is dependent upon the I/O pins,
which comprise the synch timing loop. This loop is
formed from PHERR to PHINIT and PCLK to PIC LK.
The FIFO can be thought of as a memory stack that
can be initialized by PHINT or LOCKDET. The PHERR
signal is a pointer that goes high when a potential timing mismatch is detected between PICLK and the internally generated PC LK clock. When PHERR is fed back
to PHINIT, it initializes the FIFO so that it does not overflow or underflow.
The internally generated divide-by-16 clock is used to
clock out data from the FIFO. PHINIT and LOCKDET
signals will center the FIFO after the third PICLK pulse.
This is done to ensure that PIC LK is stable. This
scheme allows the user to have an infinite PC LK to
PICLK delay through the ASIC. Once the FIFO is centered, the PCLK and PICLK can have a maximum drift of
±5 ns.
Agere Systems Inc.
During normal operation, the incoming data is passed
from the PICLK input timing domain to the internally
generated divide-by-16 PCLK timing domain. Although
the frequency of PICLK and PCLK are the same, their
phase relationship is arbitrary. To prevent errors
caused by short setup or hold times between the two
domains, the timing generator circuitry monitors the
phase relationship between PICLK and PCLK.
When an FIFO timing violation is detected, the phase
error (PHERR) signal pulses high. If the condition persists, PHERR will remain high. When PHERR is fed
back into the PHINIT input (by shorting them on the
printed-circuit board [PCB]), PHINIT will initialize the
FIFO if PHINIT is held high for at least two byte clocks.
The initialization of the FIFO prevents PCLK and PICLK
from concurrently trying to read and write over the
same FIFO bank.
During realignment, one to three bytes (16-bits wide)
will be lost. Alternatively, the customer logic can take in
the PHERR signal, process it, and send an output to
the PHINIT input in such a way that only idle bytes are
lost during the initialization of the FIFO. Once the FIFO
has been initialized, PHERR will go inactive.
17
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Timing Characteristics (continued)
generated clock (PCLK) only once after it has been written by the PICLK input.
Input Timing Mode 1
Since the delay in the customer ASIC is unknown, the
two clocks (PCLK and PIC LK) might drift in respect to
each other and try to perform the read and writer operation on the same bank in the FIFO at the same time.
However, before such a clock mismatch can occur,
PHERR goes high and, if externally connected to
PHINIT, will initialize the FIFO provided PHINIT
remains high for at least two byte clocks. One to three
16-bit words of data will be lost during the initialization
of the FIFO.
In the configuration shown in Figure 4, PHERR to
PHINIT has a zero delay (shorted on the PCB) and the
PCLK is used to clock 16-bit-wide data out of the customer ASIC. The FIFO in the multiplexer is 16-bits wide
and six registers deep.
The PCLK and PICLK signals respectively control the
READ and WRITE counters for the FIFO. The data
bank from the FIFO has to be read by the internally
OSCILLATOR
155.52 MHz ± 20 ppm
TXREFCLK
PCLK
DIVIDER
PLL
INTERNAL
PCLK
PICLK
CLOCK
TXD[0:15]
16
DATA
FIFO
TIMING
GENERATOR
PHERR
CENTERS
FIFO
PHINIT
CUSTOMER LOGIC
LOCKDET
TA16 TRANSPONDER
1-1020(F)
Figure 4. Block Diagram Timing Mode 1
18
18
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Timing Characteristics (continued)
high, the customer logic should start sending idle or
dummy bytes to the TA16 on the TXD[0:15] bus. This
should continue until PHERR goes low.
Input Timing Mode 2
To avoid the loss of data, idle or dummy bytes should
be sent on the T XD[0:15] bus whenever PHERR goes
high. In the configuration shown in Figure 5, the
PHERR signal is used as an input to the customer
logic. Upon detecting a high on the PHERR signal, the
customer logic should return a high signal, one that
remains high for at least two byte-clock cycles, to the
PHINIT input of the TA16. Also, when PHERR goes
The FIFO is initialized two-to-eight byte clocks after
PHINIT goes high for two byte clocks. PHERR goes
low after the FIFO is initialized. Upon detecting a low
on PHERR, the customer logic can start sending real
data bytes on TXD[0:15]. The two timing loops (PCLK to
PICLK and PHERR to PHINIT) do not have to be of
equal length.
OSCILLATOR
155.52 MHz ± 20 ppm
TXREFCLK
PCLK
DIVIDER
PLL
INTERNAL
PCLK
PICLK
CLOCK
TXD[0:15]
16
DATA
FIFO
TIMING
GENERATOR
PHERR
CENTERS
FIFO
D
PHINIT
Q
CUSTOMER LOGIC
LOCKDET
TA16 TRANSPONDER
1-1021(F)
Figure 5. Block Diagram Timing Mode 2
Agere Systems Inc.
19
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Timing Characteristics (continued)
Forward Clocking
In some applications, it is necessary to forward-clock
the data in a SONET/SDH system. In this application,
the reference clock from which the high-speed serial
clock is synthesized and the parallel data clock both
originate from the same source on the customer application circuit. The timing control logic in theTA16 transponder transmitter automatically generates an internal
load signal that has a fixed relationship to the reference
Data Sheet
March 2001
clock. The logic takes into account the variation of the
reference clock to the internal load signal over temperature and voltage. The connections required to implement this clocking method are shown in Figure 6. The
setup and hold times for PICLK to TxD[0:15] must be
met by the customer logic.
Possible problems: to meet the jitter generation specifications required by SONET/SDH, the jitter of the reference clock must be minimized. It could be difficult to
meet the SONET jitter generation specifications using
a reference clock generated from the customer logic.
OSCILLATOR
155.52 MHz ± 20 ppm
CLOCK
BUFFER
TXREFCLK
TXREFCLK
PCLK
DIVIDER
PLL
INTERNAL
PCLK
PICLK
CLOCK
TXD[0:15]
16
DATA
TIMING
GENERATOR
PHERR
FIFO
CENTERS
FIFO
PHINIT
CUSTOMER LOGIC
LOCKDET
TA16 TRANSPONDER
Figure 6. Forward Clocking of the TA16 Transmitter
20
20
1-1122(F)
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Timing Characteristics (continued)
PCLK-to-PICLK Timing
After powerup or RESET, the LOCKDET signal will go
active, signifying that the PLL has locked to the clock
provided on the TXREFCLK input. The FIFO is initialized
on the third PICLK after LOCKDET goes active. The
PCLK-to-PICLK delay (tD) can have any value before
the FIFO is initialized. The tD is fixed at the third PICLK
after LOCKDET goes active. Once the FIFO is initialized, PCLK and PICLK cannot drift more than 5.2 ns;
tCH cannot be more than 5.2 ns.
PCLK
tD
tD
PICLK
1ST
2ND
3RD
tCH
LOCKDET
ACTIVE
tCH
PCLK-TO-PICLK DELAY IS FIXED AND FIFO
IS INITALIZED AT THE THIRD RISING EDGE OF
PICLK AFTER LOCKDET GOES ACTIVE.
1123(F)
Figure 7. PCLK-to-PIC LK Timing
Agere Systems Inc.
21
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Timing Characteristics (continued)
Case 2—PHERR signal is input to the customer logic
and the customer logic outputs a signal to PHINIT:
PHERR/PHINIT
Another possible configuration is where the PHERR
signal is input into the customer logic and the customer
logic sends an output to the PHINIT input. However, the
customer logic must ensure that, upon detecting a high
on PHERR, the PHINIT signal remains high for more
than two byte clocks. If PHINIT is high for less than two
byte clocks, the FIFO is not guaranteed to be initialized.
Also, the customer logic must ensure that PHINIT goes
low after the FIFO is initialized (PHERR goes low).
Case 1— PHERR and PHINIT are shorted on the
printed-circuit board:
PHINIT would go high whenever there is a potential
timing mismatch between PCLK and PIC LK. PHINIT
would remain high as long as the timing mismatch
between PCLK and PICLK. If PHINIT is high for more
than two byte clocks, the FIFO will be initialized.
PHINIT will initialize the FIFO two-to-eight byte clocks
after it is high for at least two byte clocks, PHERR (and
thus PHINIT) goes active once the FIFI is initialized.
2 BYTE
CLOCKS
PHERR
2—8 BYTE CLOCKS
MINIMUM PULSE
WIDTH REQUIRED
TO CENTER
THE FIFO
CUSTOMER ASIC SENDS A
MINIMUM PULSE WIDTH OF
2 BYTE CLOCKS UPON DETECTING
A HIGH ON PHERR
PHINIT
PCLK
PICLK
INTERNAL
PCLK
PHERR GOES HIGH ON
DETECTING A FIFO TIMING ERROR
FIFO IS INITIALIZED 2—8 BYTE CLOCKS
AFTER PHINIT IS HIGH FOR 2 BYTE CLOCKS
1125(F)
Figure 8. PHERR/PHINIT Timing
tSTXD
tHTXD
PICLKP
TXD[0:15]
1027(F)
Figure 9. ac Input Timing
22
22
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Timing Characteristics (continued)
Table 9. Transmitter ac Timing Characteristics
Symbol
tSTXD
tHTXD
—
—
tD
Description
TxD[0:15] Setup Time w. r. t. PICLK
TxD[0:15] Hold Time w. r. t. PICLK
PCLKP/N Duty Cycle
PICLKP/N Duty Cycle
PCLK -to-PIC LK Drift After FIFO is Centered
Min
Max
Unit
1.5
0.5
40
40
—
—
—
60
60
5.2
ns
ns
%
%
ns
Table 10. Receiver ac Timing Characteristics
Symbol
—
—
tPPOUT
tSPOUT
tHPOUT
Description
Min
Max
Unit
45
—
–1
2
2
55
1.0
1
—
—
%
ns
ns
ns
ns
POC LK Duty Cycle
RxD[15:0] Rise and Fall Time1
POC LK Low to RxD[15:0] Valid prop. delay
RxD[15:0] and FP Setup Time w. r. t. POC LK
RxD[15:0] and FP Hold Time w. r. t. POCLK
1. 20% to 80%; 330 Ω to GND
POCLKP
tPPOUT
tSPOUT
tH POUT
FP
RXD[15:0]
1-1022(F)
Figure 10. Receiver Output Timing Diagram
Agere Systems Inc.
23
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Timing Characteristics (continued)
Data Sheet
March 2001
The frame and byte boundary detection block is activated by the rising edge of OOF and stays active until
the first FP pulse.
Receiver Framing
Figure 12 shows the frame and byte boundary detection activation by a rising edge of OOF and deactivation
by the first FP pulse.
Figure 11 shows a typical reframe sequence in which a
byte realignment is made. The frame and byte boundary detection is enabled by the rising edge of OOF.
Both the frame and byte boundaries are recognized
upon receipt of the first A2 byte following three consecutive A1 bytes. The third A2 byte is the first data byte to
be reported with the correct byte alignment on the outgoing data bus (RxD[15:0]). Concurrently, the frame
pulse (FP) is set high for one POCLK cycle.
Figure 13 shows the frame and byte boundary detection by the activation of a rising edge of OOF and deactivation by the FRAMEN input.
RECOVERED
CLOCK
OOF
SERIAL
DATA
A1
RXD[15:0]
A1
A1
A2
A1, A1
A1, A1
A2
A1, A1
A2
A2
A2, A2
INVALID DATA
A2, A2
A2
A2, A2
A2
A2, A2
VALID DATA
ROCLK
FP
1-1023(F)r.3
Figure 11. Frame and Byte Detection
BOUNDARY DETECTION ENABLED
OOF
FP
SEARCH
1-1024(F)
Figure 12. OOF Timing (FRAMEN = High)
24
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Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Timing Characteristics (continued)
BOUNDARY DETECTION ENABLED
OOF
FRAMEN
FP
SEARCH
1-1025(F)
Figure 13. FRAMEN Timing
TA16 TRANSPONDER
MULTIPLEXER
SONET/SDH
INTERFACE
IC
(VCC = 3.3 V)
100 Ω
TXREFCLKP
50 Ω TRANSMISSION LINES
CONNECTOR
330 Ω
330 Ω
TXREFCLKN
PLL
CLOCK
SYNTHESIZER
DIFFERENTIAL INTERFACE
TA16 TRANSPONDER
MULTIPLEXER
TXREFCLKN
0.1 µF
50 Ω TRANSMISSION LINES
CONNECTOR
300 Ω
330 Ω
60 Ω
TXREFCLKP
SONET/SDH
INTERFACE
IC
(VCC = 3.3 V)
PLL
CLOCK
SYNTHESIZER
FOR A SINGLE-ENDED INPUT,
THE INPUT IMPEDANCE IS
EQUIVALENT TO 60 Ω.
SINGLE-ENDED INTERFACE
Figure 14. Interfacing to the TxRefClk Input
Agere Systems Inc.
25
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Qualification and Reliability
To help ensure high product reliability and customer satisfaction, Agere is committed to an intensive quality program that starts in the design phase and proceeds through the manufacturing process. Optoelectronics modules
are qualified to Agere internal standards using MIL-STD-883 test methods and procedures and using sampling
techniques consistent with Telcordia Technologies * requirements. This qualification program fully meets the intent
of Telcordia Technologies reliability practices TR-NWT-000468 andTA-TSY-000983. In addition, the Agere Optoelectronics design, development, and manufacturing facility has been certified to be in full compliance with the latest ISO†-9001 Quality System Standards.
* Telcordia Technologies is a trademark of Telcordia Technologies, Inc.
† ISO is a registered trademark of the International Organization for Standardization.
Laser Safety Information
Class I Laser Product
All versions of theTA16-type transponders are classified as Class I laser products per FDA/CDRH, 21 CFR 1040
Laser Safety requirements. The transponders have been registered/certified with the FDA under Accession Number 8720009. All versions are classified as Class I laser products per IEC‡ 60825-1:1993.
CAUTION: Use of controls, adjustments, and procedures other than those specified herein may result in
hazardous laser radiation exposure.
This product complies with 21 CFR 1040.10 and 1040.11.
8.8 µm/125 µm single-mode pigtail with 900 µm tight buffer jacket and connector.
Wavelength = 1.3 µm, 1.5 µm.
Maximum power = 1.6 mW.
Product is not shipped with power supply.
Because of size constraints, laser safety labeling is not affixed to the module but is attached to the outside of the
shipping carton.
NOTICE
Unterminated optical connectors can emit laser radiation.
Do not view with optical instruments.
Electromagnetic Emissions and Immunity
The TA16 transponder will be tested against CENELEC EN50 081 part 1 and part 2, FCC 15, Class B limits for
emissions.
The TA16 transponder will be tested against CENELEC EN50 082 part 1 immunity requirements.
‡ IEC is a registered trademark of The International Electrotechnical Commission.
26
Agere Systems Inc.
Data Sheet
March 2001
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Outline Diagram
Dimensions are in inches and (millimeters).
0.50 (12.7)
3.600
(91.44)
0.28 (7.11)
TRANSMITTER
0.65
(16.51)
2.600
(66.04)
RECEIVER
0.22 (5.59)
0.75
(19.05)
0.500
(12.70)
1.50
(38.10)
0.450
(11.43)
0.30
(7.62)
1.80
(45.72)
PIN 1
34.5 (875) ± 43.0 (1100)
1.5 (38.1)
MAX
TX
0.45
(11.43)
1.840
(46.74)
CL
0.92
(22.37)
1.30
(33.02)
0.380
(9.65)
0.45
(11.43)
RX
160-PIN JAE CONNECTOR
MAT’G P/N WR-160PB-VF50-A3
MOUNTING HOLES (3 PLACES)
M2.5 x 0.45 (METRIC)
2 mm MAXIMUM LENGTH INTO PACKAGE
1-1012(F).d
Agere Systems Inc.
27
TA16-Type 2.5 Gbits/s Transponder with
16-Channel 155 Mbits/s Multiplexer/Demulitplexer
Data Sheet
March 2001
Ordering Information
ORDER CODE:
TA
16 – XX – X – XX
BASIC PART NUMBER
OPTIONS
STM LEVEL
16 = STM-16 (SONET OC-48)
APPLICATION
N1 = I-16, 1310 nm, intraoffice/(SONET short reach)
S1 = S-16.1, 1310 nm, short hauL (SONET IR-1)
S2 = S-16.2, 1550 nm, short haul (SONET IR-2)
L1 = L-16.1, 1310 nm, long hauL (SONET LR-1)
L2 = L-16.2, 1550 nm, long haul (SONET LR-2)
CONNECTOR*
C = SC
F = FC
* Other connectors may be made available.
Table 11. Ordering Information
Code
Application
Connector
Comcode
TA16N1CAA
TA16N1FAA
TA16S1CAA
TA16S1FAA
TA16S2CAA
TA16S2FAA
TA16L1CAA
TA16L1FAA
TA16L2CAA
TA16L2FAA
1310 nm, Intraoffice
1310 nm, Intraoffice
1310 nm, Short Haul
1310 nm, Short Haul
1550 nm, Short Haul
1550 nm, Short Haul
1310 nm, Long Haul
1310 nm, Long Haul
1550 nm, Long Haul
1550 nm, Long Haul
SC
FC/PC
SC
FC/PC
SC
FC/PC
SC
FC/PC
SC
FC/PC
108440066
108440074
108432907
108432915
108432923
108432931
108432865
108432873
108432881
108432899
Related Product Information
Table 12. Related Product Information
Description
Document Number
Using the Lucent Technologies Transponder Test Board Application Note
AP00-017OPTO
For additional information, contact your Agere Systems Account Manager or the following:
INTERNET:
http://www.agere.com
E-MAIL:
[email protected]
N. AMERICA: Agere Systems Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18109-3286
1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)
ASIA:
Agere Systems Hong Kong Ltd., Suites 3201 & 3210-12, 32/F, Tower 2, The Gateway, Harbour City, Kowloon
Tel. (852) 3129-2000, FAX (852) 3129-2020
CHINA: (86) 21-5047-1212 (Shanghai), (86) 10-6522-5566 (Beijing), (86) 755-695-7224 (Shenzhen)
JAPAN: (81) 3-5421-1600 (Tokyo), KOREA: (82) 2-767-1850 (Seoul), SINGAPORE: (65) 778-8833, TAIWAN: (886) 2-2725-5858 (Taipei)
EUROPE:
Tel. (44) 7000 624624, FAX (44) 1344 488 045
Agere Systems Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liabi lity is assumed as a result of their use or application.
Copyright © 2001 Agere Systems Inc.
All Rights Reserved
Printed in U.S.A.
March 2001
DS01-119OPTO (Replaces DS00-259OPTO)