AGERE TRCV012G53XE1

Preliminary Data Sheet
August 2000
TRCV012G5 (2.5 Gbits/s) and TRCV012G7 (2.5 Gbits/s and 2.7 Gbits/s)
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Features
■
TRCV012G5 supports OC-48/STM-16 data rate
■
TRCV012G7 supports:
— OC-48/STM-16 data rate
— RS (255, 239) forward error correction (FEC)
OC-48/STM-16 data rate
■
Fully-integrated limiting amplifier, clock recovery,
1:16 data demultiplexer
■
No reference clock required for CDR
■
2.5 Gbits/s data output and 2.5 GHz recovered
clock output available for wavelength division
multiplex (WDM) or regenerator applications
■
Programmable limiting amplifier offset
■
Programmable data sampling phase
■
Additional CML serial data input for system
loopback
■
Parity bit generation
■
Analog and digital loss of signal (LOS) indicators
■
Optional demultiplexer powerdown mode
conserves power
■
Single 3.3 V supply
■
Available in either MBIC 025 BiCMOS technology
or lower-power MBIC 025 silicon germanium
BiCMOS technology
■
High-speed LVPECL digital I/O
■
Jitter tolerance, transfer, and generation compliant
with the following:
— Telcordia Technologies* GR-253
— ITU-T G.825
— ITU-T G.958
■
Loss of signal compliant with the following:
— Telcordia Technologies GR-253
* Telcordia Technologies is a registered trademark of Bell Communications Research, Inc.
Applications
■
SONET/SDH line termination equipment
■
SONET/SDH add/drop multiplexers
■
SONET/SDH cross connects
■
SONET/SDH test equipment
Description
The Lucent Technologies Microelectronics Group
TRCV012G5 operates at the OC-48/STM-16 data
rate of 2.5 Gbits/s. The TRCV012G7 device operates
at either 2.5 Gbits/s or the RS FEC OC-48/STM-16
data rate of 2.7 Gbits/s. For clarity, this data sheet
refers to the TRCV012G5 serial data rate as
2.5 Gbits/s and the parallel data and reference clock
frequency as 155 MHz. (The precise rates are
2.48832 Gbits/s and 155.52 MHz.) When using the
TRCV012G7 at the FEC rate, the 2.5 Gbits/s data
rate should be interpreted as 2.7 Gbits/s and the parallel and clock frequency should be interpreted as
166 MHz. (The precise rates are 2.66606 Gbits/s and
166.62 MHz.)
The devices contain a limiting amplifier with 30 dB
gain, a clock and data recovery PLL with high-speed
serial clock and data outputs, and a 1:16 demultiplexer with differential PECL data and clock outputs.
The device provides improved optical receiver performance when used in optically amplified systems due
to a direct slice adjust input pin and a 6 ps adjustment capability in the slicing decision time. Both
devices are available in either BiCMOS or in SiGe
BiCMOS technology for lower power operation.
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Table of Contents
Contents
Page
Features .................................................................................................................................................................... 1
Applications ............................................................................................................................................................... 1
Description.................................................................................................................................................................1
Pin Information ..........................................................................................................................................................4
Functional Overview ................................................................................................................................................10
Limiting Amplifier .....................................................................................................................................................10
Limiting Amplifier Operation..................................................................................................................................10
Clock and Data Recovery (CDR).............................................................................................................................11
Clock Recovery Operation ....................................................................................................................................11
Clock Recovery PLL Loop Filter ...........................................................................................................................11
CDR Acquisition Time...........................................................................................................................................11
CDR Generated Jitter ...........................................................................................................................................11
CDR Input Jitter Tolerance ...................................................................................................................................12
CDR Jitter Transfer ...............................................................................................................................................12
Clock Recovery Jitter Tolerance and Jitter Transfer Specifications......................................................................13
Data Path Configuration Option (ENDATAN) .......................................................................................................14
High-Speed Serial Clock and Data Output Enables (ENCK2G5N, END2G5N)....................................................14
High-Speed Serial Data Output Mute (MUTE2G5N) ............................................................................................14
Data and CDR Configuration Options (REFSELN, INLOSN, MUTEDMXN).........................................................14
Decision Circuit—Adjustable Sampling Time (ASTREF, AST[4:0]).........................................................................15
Loss of Signal Detection..........................................................................................................................................16
Digital Loss of Signal (LOSDN).............................................................................................................................16
Analog Loss of Signal (LOSAN, PRG_LOSA) ......................................................................................................16
Demultiplexer Operation..........................................................................................................................................17
Parity Generation (PARITYP/N)............................................................................................................................17
Demultiplexer Powerdown (PDDMXN) .................................................................................................................17
Demultiplexer Data Mute (MUTEDMXN) ..............................................................................................................17
CK155P/N Low-Speed Output Mute (MUTE155N)...............................................................................................17
CML Output Structure (Used on Pins D2G5P/N, CK2G5P/N).................................................................................18
Choosing the Value of the External CML Reference Resistors (RREF1, RREF2) ...............................................18
Absolute Maximum Ratings.....................................................................................................................................19
Handling Precautions ..............................................................................................................................................19
Operating Conditions...............................................................................................................................................19
Electrical Characteristics .........................................................................................................................................20
Limiting Amplifier Specifications ...........................................................................................................................20
Optional Reference Frequency (REFCLKP/N) Specifications ..............................................................................20
LVPECL, CMOS, CML Input and Output Pins ......................................................................................................21
Timing Characteristics .............................................................................................................................................23
Output Timing .......................................................................................................................................................23
Outline Diagram.......................................................................................................................................................25
128-Pin QFP .........................................................................................................................................................25
Board Installation Recommendations ...................................................................................................................26
Thermal Considerations (MBIC 025 BiCMOS and MBIC 025 SiGe BiCMOS) .....................................................26
Ordering Information................................................................................................................................................27
DS00-234HSPL Replaces DS00-154HSPL to Incorporate the Following Updates.................................................27
2
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Description (continued)
Additional features include a user-programmable threshold for generating analog loss of signal (LOS) alarms, a
digital LOS transition detector, an optional reference clock input that can maintain synchronization with no data
input signal present, and a loopback data input. To reduce power consumption, the demultiplexer unit, high-speed
serial recovered data and clock output, low-speed clock, and low-speed demultiplexer clock output can be independently powered down in applications where they are not required.
The device may be used with the TTRN012G5 or TTRN012G7 transmit synthesizer and multiplexer.
ENCK2G5N
LOSDN
SLADJ
VTHP
VTHN
CK2G5P
CK2G5N
LOSS OF DATA
OFFSET CANCEL
&
SLICE ADJUST
0
END2G5N
1
D2G5P
D2G5N
MUTE2G5
LAINP
LAINN
MUTEDMX
LIMITING
AMPLIFIER
MUTE2G5N
MUTEDMXN
0
D0P
1
D0N
1
SAMPLER
CIRCUIT
ASTREF
AST[4:0]
ENDATCKN
ENDATCK
D1N
OUTPUT REGISTER
ENDATAN
D1P
1:16 DEMULTIPLEXER
ENDATA
DATAP
DATAN
0
RECOVERED CLOCK
LOSS OF SIGNAL
LOSAN
RECOVERED DATA
PRG_LOSA
D15P
D15N
PARITY
GENERATOR
PARITYP
PARITYN
PDDMX
PDDMXN
DATCKP
DATCKN
DATA
PHASE/FREQ.
DETECTION
REFCLKP
REFCLKN
1
CHARGE
PUMP
REFERENCE
PHASE/FREQ.
DETECTION
REFSELN
VCO
0
MUTE155
DIVIDE
BY 16
INLOS
INLOSN
1
0
RESETN
MUTE155N
CK155P
CK155N
RREF2
RREF1
TO DIGITAL LOGIC
LFP LFN VCP VCN
5-8067(F)r.2
Note: Diagram is representative of device functionality and conceptual signal flow. Internal implementation details may be different than shown.
Figure 1. Functional Block Diagram
Lucent Technologies Inc.
3
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
GND
VCCD
NC
ENDATAN
ENDATCKN
ENCK2G5N
END2G5N
INLOSN
LOSDN
LOSAN
MUTE2G5N
MUTEDMXN
RESETN
PDDMXN
MUTE155N
REFSELN
VCCD
REFCLKP
REFCLKN
VCCD
CK155P
CK155N
VCCD
PARITYP
PARITYN
GND
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
Pin Information
GND
1
AST4
2
102
101
D15P
AST3
3
100
D15N
AST2
4
99
VCCD
AST1
5
98
D14P
AST0
6
97
D14N
GND
7
96
D13P
VCCD
8
95
D13N
VCCA
9
94
VCCD
VCCA
10
93
D12P
NC
11
92
D12N
NC
12
91
D11P
GND
13
90
D11N
NC
14
89
VCCD
GND
15
88
D10P
VCN
16
87
D10N
LFN
17
86
GND
LFP
18
85
D9P
VCP
19
84
D9N
GND
20
83
D8P
GND
21
82
D8N
VCCA
22
81
VCCD
VCCA
23
80
D7P
VCCLA
24
79
D7N
PRG_LOSA
25
78
D6P
SLADJ
26
77
D6N
VCCLA
27
76
VCCD
VTHP
28
75
D5P
GND
29
74
D5N
LAINP
30
73
D4P
GND
31
72
D4N
LAINN
32
71
VCCD
GND
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
DATAN
VCCD
GND
D2G5P
D2G5N
GND
CK2G5P
CK2G5N
GND
VCCD
D0N
D0P
VCCD
D1N
D1P
D2N
D2P
GND
GND
46
65
DATAP
38
45
GND
GND
VCCD
66
44
37
DATCKN
GND
ASTREF
43
67
DATCKP
36
42
GND
GND
VCCD
68
41
35
RREF1
D3N
VCCLA
40
D3P
69
39
70
34
GND
33
RREF2
GND
VTHN
5-8071(F)r.5
Figure 2. Pin Diagram of 128-Pin QFP (Top View)
4
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Pin Information (continued)
Note: In Table 1, when operating the TRCV012G7 device at the OC-48/STM-16 rate, 2.5 Gbits/s should be interpreted as 2.48832 Gbits/s. When operating the TRCV012G7 device at the RS FEC OC-48/STM-16 rate,
2.5 Gbits/s should be interpreted as 2.66606 Gbits/s. (A similar interpretation should be made for 2.5 GHz.)
Table 1. Pin Descriptions—2.5 Gbits/s and Related Signals
Pin
30
32
50
51
Symbol*
LAINP
LAINN
D2G5P
D2G5N
Type†
I
Level
Analog
O
CML
Name/Description
Limiting Amplifier Inputs (2.5 Gbits/s).
ac coupling required.
Data Output (2.5 Gbits/s NRZ). 2.5 Gbits/s differential data
output.
■
Pins are high impedance when END2G5N = 1.
Pins are active but forced to differential logic low when
MUTE2G5N = 0.
Enable D2G5P/N Data Outputs (Active-Low).
0 = D2G5P/N buffer enabled
1 or no connection = D2G5P/N buffer powered off
Mute D2G5P/N Data Output (Active-Low).
0 = muted
1 or no connection = normal data
Recovered Clock Output (2.5 GHz). 2.5 GHz recovered differential clock output. Pins are high impedance when ENCK2G5N = 1.
■
122
END2G5N
Iu
CMOS
118
MUTE2G5N
Iu
CMOS
53
54
123
CK2G5P
CK2G5N
ENCK2G5N
O
CML
Iu
CMOS
41
RREF1
I
Analog
40
RREF2
I
Analog
28
34
26
VTHP
VTHN
SLADJ
I
Analog
I
Analog
119
25
LOSAN
PRG_LOSA
O
I
120
121
LOSDN
INLOSN
O
Iu
18
17
19
16
LFP
LFN
VCP
VCN
O
I
Enable CK2G5P/N Clock Output (Active-Low).
0 = CK2G5P/N buffer enabled
1 or no connection = CK2G5P/N buffer powered off
Resistor Reference 1. CML current bias reference resistor. (See
Table 16, page 22 for values.)
Resistor Reference 2. CML bias reference resistor. Place a
1.5 kΩ resistor to VCCD.
Voltage Threshold Adjust Input. This input is for monitoring
purposes only and should be left open (see Figure 3 on page 10).
Slice Level Adjustment. Adjusts slice level for the limiting amp
(see Figure 3 on page 10).
Open Drain Loss of Analog Signal (Active-Low).
Analog
Programming Voltage for LOSA Threshold. Programming
voltage is scaled (see Figure 7 on page 16).
Open Drain Loss of Digital Data (Active-Low).
CMOS
Input Loss of Signal (Active-Low). Forces VCO to decrease to
its minimum frequency.
0 = force VCO low
1 or no connection = normal operation
Analog
Loop Filter PLL. Connect LFP to VCP, and LFN to VCN.
Analog
VCO Control. Connect VCP to LFP, and VCN to LFN.
* Differential pins are indicated by the P and N suffixes. For nondifferential pins, N at the end of the symbol name designates active-low.
† I = input, O = output. Iu = an internal pull-up resistor on this pin, Id = an internal pull-down resistor on this pin, It = an internal termination
resistance of 50 Ω on this pin.
Lucent Technologies Inc.
5
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Pin Information (continued)
Table 1. Pin Descriptions—2.5 Gbits/s and Related Signals (continued)
Pin
43
44
124
Symbol*
DATCKP
DATCKN
ENDATCKN
Type†
It
Level
CML
Name/Description
Clock Input for DATAP/N. Buffer is powered down when
ENDATCKN = 1.
Iu
CMOS
46
47
125
DATAP
DATAN
ENDATAN
It
CML
External DATCKP/N Clock Select (Active-Low). Selects
external DATCKP/N clock to demultiplexer.
0 = select DATCKP/N
1 or no connection = select VCO clock
Data Input for CML. Use this input for system loopback
data when LAINP/N is used.
Iu
CMOS
37
ASTREF
I
Analog
2
3
4
5
6
AST4
AST3
AST2
AST1
AST0
Id
CMOS
Enable DATAP/N Inputs (Active-Low). Selects DATAP/N
as data source rather than limiting amplifier output.
0 = select DATAP/N
1 or no connection = select LAINP/N
Adjustable Sampling Circuit Reference Resistor.
Connect a 2.1 kΩ resistor to VCCA.
Adjustable Sampling Time Control Inputs. AST[4:0]
allows introduction of an offset into the sampling time. The
most significant bit (A4) is the sign bit and bits A[3:0]
represent the magnitude. (See the Decision Circuit—
Adjustable Sampling Time (ASTREF, AST[4:0]) section,
page 15.)
A4 is the polarity bit as follows:
1 = advance
0 = delay sampling point
AST[3:0] provides adjustments in steps (increments or
decrements) of 6.25 ps in the sampling instant.
* Differential pins are indicated by the P and N suffixes. For nondifferential pins, N at the end of the symbol name designates active-low.
† I = input, O = output. Iu = an internal pull-up resistor on this pin, Id = an internal pull-down resistor on this pin, It = an internal termination resistance of 50 Ω on this pin.
6
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Pin Information (continued)
Note: In Table 2, when operating the TRCV012G7 device at the OC-48/STM-16 rate, 155 Mbits/s should be interpreted as 155.52 Mbits/s. When operating the TRCV012G7 device at the RS FEC OC-48/STM-16 rate,
155 Mbits/s should be interpreted as 166.62 Mbits/s. (A similar interpretation should be made for 155 MHz.)
Table 2. Pin Descriptions—155.52 Mbits/s and Related Signals
Pin
101
100
98
97
96
95
93
92
91
90
88
87
85
84
83
82
80
79
78
77
75
74
73
72
70
69
63
62
61
60
58
57
Symbol*
D15P
D15N
D14P
D14N
D13P
D13N
D12P
D12N
D11P
D11N
D10P
D10N
D9P
D9N
D8P
D8N
D7P
D7N
D6P
D6N
D5P
D5N
D4P
D4N
D3P
D3N
D2P
D2N
D1P
D1N
D0P
D0N
Type†
O
Level
LVPECL
LVPECL
LVPECL
Name/Description
Data Output (155 Mbits/s). 155 Mbits/s differential data output.
D15 is the most significant bit and is the first received on the
LAINP/N or DATAP/N input.
When PDDMXN = 0, data outputs can be left floating to reduce
power consumption.
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
LVPECL
* Differential pins are indicated by the P and N suffixes. For nondifferential pins, N at the end of the symbol name designates active-low.
† I = input, O = output. Iu = an internal pull-up resistor on this pin, Id = an internal pull-down resistor on this pin, It = an internal termination
resistance of 50 Ω on this pin.
Lucent Technologies Inc.
7
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Pin Information (continued)
Table 2. Pin Descriptions—155.52 Mbits/s and Related Signals (continued)
Pin
115
Symbol*
PDDMXN
Type†
Iu
Level
CMOS
117
MUTEDMXN
Iu
CMOS
108
107
CK155P
CK155N
O
LVPECL
114
MUTE155N
Iu
CMOS
105
104
111
110
PARITYP
PARITYN
REFCLKP
REFCLKN
O
LVPECL
I
LVPECL
Name/Description
Powerdown Demultiplexer Circuit (Active-Low).
0 = demultiplexer powered off, D[15:0]P/N and PARITYP/N
are high-impedance
1 or no connection = demultiplexer powered on
Mute Data to Demultiplexer Circuit (Active-Low).
0 = mute data
1 or no connection = normal data
Recovered Clock Output (155 MHz).
155 MHz recovered differential clock output. Pins are active
but forced to differential logic low when MUTE155N = 0.
Mute CK155P/N Clock Output (Active-Low). Forces
CK155P/N to logic low when MUTE155N is active.
0 = muted
1 or no connection = enabled
Parity Input Over Data (D[15:0]). Active only when
PDDMXN = 1.
Reference Clock Input (155 MHz). This clock is optional. If
applying the REFCLKP/N, set the REFCLKP/N to one of
the following frequencies:
■
155.52 MHz if using the TRCV012G5, or the
TRCV012G7 at the 0C-48/STM-16 rate of 2.48832 GHz.
166.62 MHz if using the TRCV012G7 at the RS FEC
0C-48/STM-16 rate of 2.66606 GHz.
Reference Select to PLL. Selects LAINP/N or DATAP/N, or
REFCLKP/N as the input to the CDR PLL.
0 = select REFCLKP/N
1 or no connection = select LAINP/N or DATAP/N
■
113
REFSELN
Iu
CMOS
* Differential pins are indicated by the P and N suffixes. For nondifferential pins, N at the end of the symbol name designates active-low.
† I = input, O = output. Iu = an internal pull-up resistor on this pin, Id = an internal pull-down resistor on this pin, It = an internal termination resistance of 50 Ω on this pin.
8
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Pin Information (continued)
Table 3. Pin Descriptions—Global Signal
Pin
116
Symbol*
RESETN
Type†
Iu
Level
CMOS
Name/Description
Reset (Active-Low). Resets all synchronous logic. During
a reset, the true data outputs are in the low state and the
barred data outputs are in the high state.
0 = reset
1 or no connection = normal operation
* Differential pins are indicated by the P and N suffixes. For nondifferential pins, N at the end of the symbol name designates active-low.
† I = input, O = output. Iu = an internal pull-up resistor on this pin, Id = an internal pull-down resistor on this pin, It = an internal termination resistance of 50 Ω on this pin.
Table 4. Pin Descriptions—Power and No-Connect Signals
Note: VCCA, VCCLA, and VCCD have the same dc value, which is represented as VCC unless otherwise specified.
However, high-frequency filtering is suggested between the individual supplies.
Pin
9, 10, 22, 23
24, 27, 35
8, 42, 45, 48,
56, 59, 71, 76,
81, 89, 94, 99,
106, 109, 112,
127
13, 15, 20, 21
29, 31, 33
1, 7, 36, 38,
39, 49, 52, 55,
64—68, 86,
102, 103, 128
11, 12, 14, 126
Symbol*
VCCA
VCCLA
VCCD
Type†
I
I
I
Level
Power
Power
Power
Name/Description
Analog Power Supply (3.3 V).
Limiting Amplifier Power Supply (3.3 V).
Digital Power Supply (3.3 V).
GND
I
Ground
Ground.
NC
No Connection. These pins must be left open.
* Differential pins are indicated by the P and N suffixes. For nondifferential pins, N at the end of the symbol name designates active-low.
† I = input, O = output. Iu = an internal pull-up resistor on this pin, Id = an internal pull-down resistor on this pin, It = an internal termination resistance of 50 Ω on this pin.
Lucent Technologies Inc.
9
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Functional Overview
The Lucent Technologies Microelectronics Group TRCV012G5 operates at the OC-48/STM-16 data rate of
2.5 Gbits/s.* The TRCV012G7 device operates at either 2.5 Gbits/s or the RS FEC OC-48/STM-16 data rate of
2.7 Gbits/s. The device performs the data detection, clock recovery, and 1:16 demultiplexing operations required to
support 2.5 Gbits/s applications compliant with Telcordia Technologies and ITU standards. A differential limiting
amplifier with an adjustable threshold amplifies the 2.5 Gbits/s serial data waveform from an off-chip transimpedance amplifier (TIA). Alternatively, a CML logic level input can be selected as the data source. A PLL recovers the
clock which is used to retime the data. The decision sampling phase can be adjusted for optimal system performance. The 2.5 Gbits/s serial data and the 2.5 GHz recovered clock signal are available at CML outputs, or alternatively, they can be disabled or the data can be muted. A 1:16 data demultiplexer performs the serial-to-parallel
conversion and generates 16 parallel outputs at a 155 Mbits/s rate as well as a parity indicator. The parallel output
data is aligned to a 155 MHz clock derived from the 2.5 GHz recovered clock. Loss of analog signal (LOSA) and
loss of digital transitions (LOSD) are indicated. A 155 MHz reference clock may optionally be applied to serve as a
frequency reference when data timing is lost.
Limiting Amplifier
Limiting Amplifier Operation
The limiting amplifier receives the input serial 2.5 Gbits/s data waveform from a transimpedance amplifier interface.
The limiting amplifier inputs are internally terminated with 50 Ω resistors to ensure high input return loss performance. The signal is amplified with a small signal gain of approximately 30 dB to a saturation level of approximately 800 mVp-p in order to provide a digital waveform to the clock and data recovery PLL. Full limiting is
guaranteed for inputs of 15 mVp-p or greater on each input rail (30 mVp-p differential). If the input signal level is
below a user-configurable threshold for a sufficiently long period of time, the LOSA signal is asserted. (For more
detail on the LOSA functions, see the Analog Loss of Signal (LOSAN, PRG_LOSA) section on page 16.)
A typical interface between the lightwave receiver and the limiting amplifier is shown in Figure 3.
Note: It is recommended to use a differential interface from the lightwave receiver device with ac coupling.
The slicing level can be adjusted by varying the voltage on the SLADJ pin within ±300 mV of VCC/2. This feature
can be used to improve BER performance in optical receivers and optical amplifier systems. The relationship
between the external voltage and the slicing level is given in Table 9 on page 20. If the voltage at this pin is tied
below 0.5 V, the external slice adjustment is disabled and only the internal offset cancellation feature is active. The
user should connect the SLADJ pin to GND if the slice adjust feature is not needed. The limiting amplifier will perform in accordance with the specifications shown in Table 9.
SLADJ
OFFSET CANCEL
&
SLICE ADJUST
VTHP
VTHN
LIGHTWAVE RECEIVER
DEVICE
0.047 µF
0.1 µF
TIA
LAINP
0.047 µF
50 Ω
LAINN
50 Ω
LIMITING
AMPLIFIER
0.1 µF
5-8068(F)
Figure 3. Typical TIA to Limiting Amplifier Interface
* The OC-48/STM-16 data rate of 2.48832 Gbits/s is typically approximated as 2.5 Gbits/s in this document when referring to the application
rate. The RS FEC OC-48/STM-16 data rate is 2.66606 Gbits/s and is approximated as 2.7 Gbits/s in this document. Similarly, the OC-3/
STM-1 data rate of 155.52 Mbits/s is typically approximated as 155 Mbits/s, and the RS FEC OC-3/STM-1 data rate of 166.62 Mbits/s is
approximated as 166 Mbits/s. The exact frequencies are used only when necessary for clarity.
10
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Clock and Data Recovery (CDR)
Clock Recovery Operation
The CDR circuit uses a PLL to extract the clock and retime the 2.5 Gbits/s data. The 2.5 Gbits/s data and the
2.5 GHz recovered clock are available as outputs, as well as a 155 MHz clock derived from the recovered clock.
Clock Recovery PLL Loop Filter
A typical loop filter that meets the OC-48 jitter transfer template is shown in Figure 4. Connect the filter components and also connect LFP to VCP and connect LFN to VCN. The component values can be varied to adjust the
loop dynamic response (see Table 5).
Table 5. Clock Recovery Loop Filter Component Values
Components
C1*
C2, C3
R1
R2
Values for 2 MHz Loop Bandwidth
0.47 µF ± 10%
10 pF ± 20%
82.5 Ω ± 5%
100 kΩ ± 5%
* Capacitor C1 should be either ceramic or nonpolar.
R2
LFP/VCP
C1
LFN/VCN
R1
C2
C3
5-8061(F).a
Figure 4. Clock Recovery PLL Loop Filter Components
CDR Acquisition Time
The limiting amplifier plus CDR will acquire phase/frequency lock within 10 ms after powerup and a valid SONET
signal or a 223 – 1 PRBS data signal is applied.
CDR Generated Jitter
The limiting amplifier plus CDR’s generated jitter performance meets the requirements shown in Table 6. These
specifications apply to the jitter generated at the 2.5 Gbits/s recovered clock pins (CK2G5P/N) when the following
occur: no jitter is present on the input, the limiting amplifier’s input signal is within the valid level range given in
Table 9 on page 20, and the data sequence is a valid OC-48 SONET/SDH signal.
Table 6. Clock and Data Recovery Generated Jitter Specifications
Parameter
Typical
Generated Jitter (p-p):
Measured with 12 kHz to 20 MHz Bandpass Filter
Generated Jitter (rms):
Measured with 12 kHz to 20 MHz Bandpass Filter
Unit
0.06
Max
(Device)*
0.10
UIp-p
0.008
0.01
UIrms
* This denotes the device specification for system SONET/SDH compliance when the loop filter in Table 5 and Figure 4 is used.
Lucent Technologies Inc.
11
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Clock and Data Recovery (CDR) (continued)
CDR Input Jitter Tolerance
The limiting amplifier plus CDR’s jitter tolerance performance meets the requirement shown in Figure 5 on page 13
when the limiting amplifier’s input signal is within the valid level range given in Table 9 on page 20, the loop filter in
Figure 4 is used, and the data sequence is a valid OC-48 SONET/SDH signal.
CDR Jitter Transfer
Using the loop filter in Figure 4, the CDR’s jitter transfer performance meets the requirement shown in Figure 6
when the input jitter magnitude is within the jitter tolerance requirements given in Figure 5 and the data sequence is
a valid OC-48 SONET/SDH signal. This specification applies to the jitter transferred from the limiting amplifier’s
input to the 2.5 Gbits/s recovered clock pins (CK2G5P/N).
12
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Clock and Data Recovery (CDR) (continued)
Clock Recovery Jitter Tolerance and Jitter Transfer Specifications
100 UI
(10 Hz, 15 UIp-p)
(600 Hz, 15 UIp-p)
10 UI
(100 kHz, 1.5 UIp-p)
(6 kHz, 1.5 UIp-p)
1 UI
0.1 UI
(1 MHz, 0.15 UIp-p)
0.01 UI
10
100
1k
10k
100k
1M
10M
FREQUENCY (Hz)
5-8069(F)r.1
Figure 5. Receiver Jitter Tolerance
(2 MHz, 0.1 dB)
0
JITTER OUT/JITTER IN (dB)
10
20
30
40
50
60
1k
10k
100k
1M
10M
100M
FREQUENCY (Hz)
5-8062(F)r.2
Figure 6. Receiver Jitter Transfer
Lucent Technologies Inc.
13
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Clock and Data Recovery (CDR) (continued)
Data Path Configuration Option (ENDATAN)
Either the limiting amplifier (LAINP/N) or a CML logic level input (DATAP/N) can be selected as the source of the
2.5 Gbits/s data signal. The DATAP/N input can be used if the limiting amplifier is not needed, or it can be used as
a system loopback path when the limiting amplifier is the normal data path. If the limiting amplifier is not used in
normal operation, the LAINP/N pins should be grounded through a series ac coupling of 0.1 µF.
High-Speed Serial Clock and Data Output Enables (ENCK2G5N, END2G5N)
Separate output enables are provided for the 2.5 GHz recovered clock output (CK2G5P/N) and the 2.5 Gbits/s
data output (D2G5P/N). These enables are active-low CMOS inputs with internal pull-up resistors. A ground or
logic low applied to the pin enables the corresponding output. When disabled, the pins should be either left floating,
or be connected to a load which returns to VCC. The high-speed serial clock and data outputs must not be connected directly to ground when they are disabled.
High-Speed Serial Data Output Mute (MUTE2G5N)
The 2.5 Gbits/s data output (D2G5P/N) may be forced to a logic-low state using MUTE2G5N. This may be desirable if the quality of the input data is suspect, as may be the case under LOSA or LOSD conditions. MUTE2G5N is
an active-low CMOS input.
Data and CDR Configuration Options (REFSELN, INLOSN, MUTEDMXN)
A 155 MHz clock (REFCLKP/N) may optionally be provided as a frequency reference to the clock recovery PLL in
order to control the recovered clock frequency when data timing is lost, as may be the case under LOSA or LOSD
conditions. If REFCLKP/N is provided, REFSELN can be used to select REFCLKP/N as the frequency reference to
the clock recovery PLL.
The INLOSN pin will force the VCO to decrease to its minimum frequency. This will prevent the VCO frequency
from drifting to a high value during invalid signal conditions. INLOSN may be used to limit the recovered clock frequency in systems that do not provide a REFCLKP/N signal.
The MUTEDMXN pin will force logic-low data into the demultiplexer, and therefore, keep all demultiplexer outputs
in the logic-low state. MUTEDMXN will not affect the operation of the CDR circuits. This may be desirable if the
quality of the input data is suspect as may be the case under LOSA or LOSD conditions.
The user may utilize the REFSELN, INLOSN, and MUTEDMXN pins in any combination to achieve the desired
response under LOS conditions.
14
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Decision Circuit—Adjustable Sampling Time (ASTREF, AST[4:0])
The adjustable sampling time (AST) feature allows a deliberate time offset to be introduced for the data recovery
sampling instant relative to the recovered clock. The sampling instant is normally set by the clock recovery phaselocked loop (PLL) to be midway between the mean values of adjacent NRZ data polarity transitions, which provides an ideal setup and hold time margin of one half the data period. By setting the AST[4:0] control bits, the user
may shift the instant at which the PLL’s recovered clock samples the receive data eye. The AST[4] bit acts as a
polarity setting, AST[3] represents the most significant magnitude bit, and AST[0] represents the least significant
magnitude bit. Since this results in two decoded zero time offset states, AST[4:0] = 00000 is used to disable the
sampling offset feature entirely and will result in traditionally defined midpoint sampling, whereas AST[4:0] = 10000
will also result in midpoint sampling by using the AST feature in its zero time offset condition. With AST[4] set to a
logic high, increasing the AST[3:0] hexadecimal code causes the sampling point to monotonically advance in time;
with AST[4] set to a logic low, the sample time is delayed more as AST[3:0] increases. The ASTREF pin should be
tied to the positive power supply through a low-capacitance 1%, 2.1 kΩ resistor. This provides a stable reference
resistor to the AST circuitry.
The AST control bit configurations and corresponding offset times are shown in Table 7.
Table 7. Adjustable Sampling Time (AST) Control Code
Note: When operating the TRCV012G7 at the FEC rate, the 6.25 ps
step should be scaled down by 7%.
AST[4:0]
Time Offset
(ps)
AST[4:0]
Time Offset
(ps)
01111
–93.75
10000
0.00
01110
–87.50
10001
6.25
01101
–81.25
10010
12.50
01100
–75.00
10011
18.75
01011
–68.75
10100
25.00
01010
–62.50
10101
31.25
01001
–56.25
10110
37.50
01000
–50.00
10111
43.75
00111
–43.75
11000
50.00
00110
–37.50
11001
56.25
00101
–31.25
11010
62.50
00100
–25.00
11011
68.75
00011
–18.75
11100
75.00
00010
–12.50
11101
81.25
00001
–6.25
11110
87.50
00000
0.00
11111
93.75
Lucent Technologies Inc.
15
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Loss of Signal Detection
The loss of signal circuits are used to detect the conditions of low input signal level or no data transitions at the
input. The LOSDN and LOSAN signals can be processed and/or filtered to meet various system-dependent
requirements on declaring loss of signal.
Digital Loss of Signal (LOSDN)
The LOSDN signal alarm is set when no transitions appear in the data path for more than 2.3 µs. The LOSDN signal will become active before 100 µs of no transitions has occurred. When ac coupling the 2.5 Gbits/s data to the
high gain limiting amplifier, in the presence of no significant amplitude data transitions, noise at the limiting amplifier’s input may be amplified and appear to be a data transition. This may change the state of LOSDN.
Analog Loss of Signal (LOSAN, PRG_LOSA)
Low signal levels are detected by the limiting amplifier with an optional user-programmable analog loss of signal
(LOSA) threshold. As shown in Figure 7, applying a voltage to the PRG_LOSA pin will adjust the LOSA trip point.
When the voltage on PRG_LOSA is 0 V, LOSAN will never be active even if the level at the limiting amplifier input
is zero. When the voltage on PRG_LOSA is greater than approximately 1 V and less than 2 V, LOSAN will always
be active regardless of the signal level at the limiting amplifier input. If the voltage of the PRG_LOSA pin exceeds
2 V, the threshold defaults to approximately 12 mVp-p differential. This voltage can be adjusted while monitoring
the BER of the system, and is typically set to activate LOSAN for input levels corresponding to a BER of just above
10–3. LOSAN will not be asserted unless the alarm condition exists for at least 2.3 µs. The LOSAN pin will be deasserted when the input level becomes greater than the LOSA threshold by an amount corresponding to 1 dB (typical) optical power input. The input resistance of the PRG_LOSA pin is typically 50 kΩ, so a resistor voltage divider
between VCC and ground may be used to set the PRG_LOSA level if the VCC tolerance and variability is adequate.
45
VIN (mVp-p) AT WHICH LOSA ACTIVATES
40
DATA PATTERN
35
1/1
PRBS
8/8
30
25
20
15
10
5
0
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
PROGRAM VOLTAGE
5-8070(F)r.2
Figure 7. Typical LOSA Threshold vs. PRG_LOSA Voltage vs. Data Pattern
16
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Demultiplexer Operation
The serial 2.5 Gbits/s data is clocked into a 1:16 demultiplexer by the recovered 2.5 GHz clock. The demultiplexed
parallel data is retimed with a 155 MHz clock that is derived from the recovered clock. The relationship between
the serial input data and the parallel D[15:0] bits is given in Figure 8. D15 is the bit that was received first in time in
the serial input data stream.
D15
(MSB)
D14
D1
(D15 RECEIVED FIRST)
D0
(LSB)
D15
(D0 RECEIVED LAST)
TIME
5-8063(F).a
Figure 8. Serial Input to Parallel Output Data Relationship
Parity Generation (PARITYP/N)
The parity pin (PARITYP/N) is a logic 0 when the number of 1s in the 16-bit output register is an even number, and
the parity pin is a logic 1 when the number of 1s in the output register is an odd number.
Demultiplexer Powerdown (PDDMXN)
The entire demultiplexer and parity generator functionality can be powered down for systems requiring only the
2.5 GHz clock and data outputs. Setting PDDMXN = 0 powers down the demultiplexer and parity generation functions as well as the CK155P/N output clock signal. When PDDMXN = 0, the D[15:0] and PARITYP/N pins should
be left unconnected.
Demultiplexer Data Mute (MUTEDMXN)
Setting the MUTEDMXN = 0 mutes the data going into the demultiplexer and forces all zeros to appear at the parallel outputs (D[15:0]).
CK155P/N Low-Speed Output Mute (MUTE155N)
The 155 MHz low-speed clock output (CK155P, CK155N) can be forced to logic low by setting MUTE155N, which
is an active-low CMOS input with an internal pull-up resistor. A ground or logic low applied to MUTE155N mutes
the CK155P/N output.
Lucent Technologies Inc.
17
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
CML Output Structure (Used on Pins D2G5P/N, CK2G5P/N)
The CML architecture is essentially a current-steering mechanism combined with an amplifier. This makes the output swing of the signal a function of the termination resistor and the programmable output current. The user should
connect external termination resistors from the CML output pins to VCC. The on-chip, 100 Ω pull-up resistors provide a dc path when using an ac-coupled load.
The voltage swing of a CML signal is typically 400 mV, half that of ECL/PECL. The lower pulse amplitude reduces
noise transients, crosstalk, and EMI. It also uses half the amount of current through the termination resistors. The
schematic of a typical CML output structure is shown in Figure 9.
DEVICE-INTERNAL CML OUTPUT BUFFER CIRCUIT
VCC
VCC
VCC
VCC
50 Ω
100 Ω
50 Ω
100 Ω
IOUT
EXTERNAL OUTPUT TERMINATION
IOUT
VCC
RREF1
+
18X
VREF
–
RREF2
5-8065(F)r.2
Figure 9. Typical CML Output Structure
Choosing the Value of the External CML Reference Resistors (RREF1, RREF2)
The flexibility of the CML interface permits certain parameters to be customized for a particular application. The
RREF1 resistor controls the CML output driver current source. Adjusting this tail current and termination resistors
will allow signal amplitude control (see the CML output specifications for limitations, page 22 and page 24) and
flexibility in termination schemes.
With RREF2 set to 1.5 kΩ, the equation for the CML output current is the following:
Iout = (18)*(1.21)/RREF1
The CML outputs have on-chip 100 Ω load resistors to VCC in order to accommodate capacitive ac coupling. With
a 50 Ω 1% load, the effective load resistance will be 33.33 Ω ± 6%. For a 400 mV voltage swing into the 50 Ω load,
set RREF1 to 1.8 kΩ. For a 600 mV voltage swing, set RREF1 to 1.2 kΩ. In both cases, RREF2 remains fixed at a
value of 1.5 kΩ.
18
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
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 operational sections of the data sheet. Exposure to absolute maximum ratings for extended
periods can adversely affect device reliability.
Parameter
Power Supply Voltage (VCC)
Storage Temperature
Pin Voltage
Min
—
–40
GND – 0.5
Max
4.0
125
VCC + 0.5
Unit
V
°C
V
Handling Precautions
Although protection circuitry has been designed into this device, proper precautions should be taken to avoid exposure to electrostatic discharge (ESD) during handling and mounting. Lucent employs a human-body model (HBM)
and charged-device model (CDM) for ESD-susceptibility testing and protection design evaluation. ESD voltage
thresholds are dependent on the circuit parameters used in the defined model. No industrywide standard has been
adopted for the CDM. However, a standard HBM (resistance = 1500 Ω, capacitance = 100 pF) is widely used and,
therefore, can be used for comparison purposes:
Device
TRCV012G5
TRCV012G7
Voltage
≥200 V
≥200 V
Operating Conditions
Table 8. Recommended Operating Conditions
Parameter
Power Supply (dc voltage)
Ground
Input Voltage:
Low
High
Temperature:
Ambient
Junction
Power Dissipation:
MBIC 025 BiCMOS
MBIC 025 SiGe BiCMOS
Lucent Technologies Inc.
Symbol
—
—
VIL
VIH
Min
Typ
Max
3.135
3.3
3.465
—
—
—
(See Table 11, (See Table 11, (See Table 11,
Table 13,
Table 13,
Table 13,
Table 15.)
Table 15.)
Table 15.)
Unit
V
V
V
V
TA
—
–40
0
—
—
85
125
°C
°C
PD
PD
—
—
2.5
1.45
3.43
1.73
W
W
19
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Electrical Characteristics
Limiting Amplifier Specifications
Table 9. Limiting Amplifier Characteristics
Parameter
Data Input Level for Full Amplifier Limiting
(differential input)
Small-signal Gain
Small-signal Bandwidth
Input Referred Wideband Noise
(dc—2.5 GHz)
Input Return Loss (LAINP/LAINN pins):
100 MHz—2 GHz
2 GHz—3 GHz
Input Slice Level Adjustment
SLADJ Input Range
Slice Feature Disable Voltage (SLADJ)
Min
30
Typical
—
Max
1200
Unit
mVp-p
26
3
—
30
—
—
32
—
170
dB
GHz
µVrms
—
—
—
VCC/2 – 0.3
—
—
—
0.01*(SLADJ – VCC/2)
—
—
–20
–15
—
Vcc/2 + 0.3
0.5
dB
dB
V
V
V
Optional Reference Frequency (REFCLKP/N) Specifications
The CDR operates without any reference clock. However, a reference clock input is available should the user want
to maintain the CDR frequency lock without any data input.
■
When using the TRCV012G5 device, a 155.52 MHz differential LVPECL clock can be applied to the
REFCLKP/N input.
■
When using the TRCV012G7 device at the OC-48/STM-16 rate, a 155.52 MHz differential LVPECL clock can be
applied to the REFCLKP/N input.
■
When using the TRCV012G7 device at the RS FEC OC-48/STM-16 rate, a 166.62 MHz differential LVPECL
clock can be applied to the REFCLKP/N input.
Table 10 provides the characteristics of the REFCLKP/N input.
Table 10. Reference Frequency Characteristics
Parameter
Reference Frequency (REFCLKP/N)
Reference Frequency Tolerance*
Duty Cycle
Temperature†
Supply Voltage†
Min
—
—
–20
40
–40
3.10
Typ
155.52
166.62
—
—
—
—
Max
—
—
20
60
85
3.60
Unit
MHz
MHz
ppm
%
°C
V
* Includes effects of power supply variation, temperature, electrical loading, and aging. The ±20 ppm tolerance is
required to meet SONET/SDH requirements if the reference frequency is used for system clocking when timing
recovery is lost.
† Specified range is to be compatible with environmental specification of TRCV012G5 or TRCV012G7. Applications
requiring a reduced temperature range may specify the reference frequency oscillator accordingly.
20
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Electrical Characteristics (continued)
LVPECL, CMOS, CML Input and Output Pins
Notes:
1. For Table 11 through Table 18, VCC = 3.3 V ± 5%, TA = –40 °C to +85 °C; these tables apply to both MBIC 025
BiCMOS and MBIC 025 SiGe BiCMOS technologies.
2. For more information on interpreting CML specifications, see the CML Output Structure (Used on Pins
D2G5P/N, CK2G5P/N) section on page 18.
Table 11. LVPECL Input Pin Characteristics
Applicable
Pins
REFCLKP/N
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
VIH
VIL
IIH
IIL
Input Voltage High
Input Voltage Low
Input Current High Leakage
Input Current Low Leakage
Referred to VCC
Referred to VCC
VIN = VIH (max)
VIN = VIL (min)
–1165
–1810
—
5
—
—
—
—
–880
–1475
20
—
mV
mV
µA
µA
Table 12. LVPECL Output Pin Characteristics
Applicable
Pins
D[15:0]P/N,
PARITYP/N,
CK155P/N
Symbol
Parameter
Conditions
VOH
Output Voltage High
VOL
Output Voltage Low
Load = 50 Ω
connected to
VCC – 2.0 V
Load = 50 Ω
connected to
VCC – 2.0 V
Min
Typ
Max
Unit
VCC – 1.31 VCC – 1.20 VCC – 0.90
V
VCC – 1.95 VCC – 1.88 VCC – 1.80
V
Table 13. CMOS Input Pin Characteristics
Applicable Symbol
Parameter
Pins
VIH
Input Voltage High
END2G5N,
ENCK2G5N,
VIL
Input Voltage Low
RESETN,
IIH
Input Current High Leakage
ENDATAN,
Input Current Low Leakage
IIL
ENDATCKN,
REFSELN,
MUTEDMXN,
PDDMXN,
MUTE155N,
MUTE2G5N
AST[4:0]
IIH
Input Current High Leakage
IIL
Input Current Low Leakage
Conditions
Min
Max
Unit
—
—
VIN = VCC
VIN = GND
VCC – 1.0
GND
—
–225
VCC
1.0
10
—
V
V
µA
µA
VIN = VCC
VIN = GND
—
–10
225
—
µA
µA
Conditions
Min
Max
Unit
RL ≥ 5 kΩ
RL ≥ 5 kΩ
—
VCC – 0.5
GND
—
VCC
0.5
30
V
V
pF
Table 14. Open Drain Output Pin Characteristics
Applicable
Pins
LOSAN,
LOSDN
Symbol
VOH
VOL
Cl
Lucent Technologies Inc.
Parameter
Output Voltage High
Output Voltage Low
Output Load Capacitance
21
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Electrical Characteristics (continued)
LVPECL, CMOS, CML Input and Output Pins (continued)
Table 15. CML Input Pin dc Characteristics
Applicable
Pins
Symbol
Parameter
DATAP/N,
DATCKP/N
VIL
Input Voltage Low
VIH
Input Voltage High
Conditions
Min
Typ
Max
Unit
—
—
VCC – 0.4
—
V
—
VCC
—
V
Conditions
Min*
Typ†
Max‡
Unit
RREF2 = 1.5 kΩ
RL = 50 Ω
All signals
differential
VCC – 1.2
VCC – 0.4
—
V
—
VCC
VCC + 0.3
V
3.6
12
18
mA
—
0
1
µA
Table 16. CML Output Pin dc Characteristics
Applicable
Pins
Symbol
Parameter
D2G5P/N,
CK2G5P/N
VOL
Output Voltage Low
VOH
Output Voltage High
IOL
Output Current Low
IOH
Output Current High
* Applies when RREF1 = 1 kΩ.
† Applies when RREF1 = 1.8 kΩ.
‡ Applies when RREF1 = 6 kΩ.
22
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Timing Characteristics
Output Timing
The timing relationships between the 155 MHz or 166 MHz output clock (CK155P/N) and the output demultiplexer
data (D[15:0]P/N) and the output parity (PARITYP/N) are shown in Figure 10.
tPERIOD
CK155P
OUTPUT
CK155N
tDD1
D[15:0]P/N
DATA 2
DATA 1
OUTPUTS
DATA 3
tDD2
PARITYP/N
PARITY 1
PARITY 2
PARITY 3
5-7726(F).fr.4
Figure 10. Transmit Timing Waveform with 155 MHz or 166 MHz Clock
The 155 MHz or 166 MHz output clock and data signals from Figure 10 are characterized in Table 17.
Table 17. LVPECL Output Pin ac Timing Characteristics
Applicable
Pins
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
CK155P/N
—
tPERIOD
All signals
differential
D[15:0]P/N,
PARITYP/N,
CK155P/N
tDD1
Duty Cycle
155.52 MHz Clock Period
166.62 MHz Clock Period
Time Delay from Clock Edge
to D[15:0]P/N Edge
Time Delay from Clock Edge
to PARITYP/N Edge
Rise, Fall Times:
20%—80%
Transition Skew Rise to Fall
48
—
—
2.9
50
6.43
6.00
3.2
52
—
—
3.9
%
ns
ns
ns
3.3
4.0
4.7
ns
200
500
800
ps
–100
0
100
ps
tDD2
tRISE,
tFALL
tSKEW
Lucent Technologies Inc.
23
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Timing Characteristics (continued)
Output Timing (continued)
The timing relationship between the 2.5 GHz or 2.7 GHz output clock (CK2G5P/N) and the 2.5 Gbits/s or
2.7 Gbits/s output data (D2G5P/N) is shown in Figure 11.
tPERIOD
CK2G5P
OUTPUT
CK2G5N
tDD
OUTPUT
D2G5P/N
DATA 1
DATA 2
DATA 3
5-7726(F).er.4
Figure 11. Transmit Timing Waveform with 2.5 GHz or 2.7 GHz Clock
The 2.5 GHz or 2.7 GHz output clock and data signals from Figure 11 are characterized in Table 18.
Table 18. CML Output Pin ac Timing Characteristics
Applicable
Pins
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
CK2G5P/N
—
Duty Cycle
2.48832 GHz Clock Period
2.66606 GHz Clock Period
Time Delay from Clock Edge
to D2G5P/N Edge
Rise, Fall Times:
20%—80%
Transition Skew Rise to Fall
RREF1 = 1.8 kΩ
RREF2 = 1.5 kΩ
RL = 50 Ω
All signals
differential
40
—
—
151
50
402
375
201
60
—
—
251
%
ps
ps
ps
50
80
120
ps
–10
0
10
ps
tPERIOD
D2G5P/N,
CK2G5P/N
tDD
tRISE,
tFALL
tSKEW
24
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Outline Diagram
128-Pin QFP
Dimensions are in millimeters.
17.20 ± 0.20
13.89 ± 0.10
8.13 (REF)
128
2.89
(REF)
103
1
102
1
5.87
(REF)
LUCENT
Code Name
YYWWL
XXXXXKNV
17.52
± 0.18
8.13
(REF)
1.600 ± 0.150
19.86
± 0.10
23.20
± 0.20
0.800 ± 0.150
DETAIL A
38
65
39
DETAIL A
64
11.43 ± 0.18
2.80 (REF)
3.30 (REF)
0.20 ± 0.06
2.89
(REF)
0.50 (TYP)
8.13 (REF)
0.000 TO 0.100
0.38 (REF)
(8.13)2 x 0.305 HEAT SINK
5-8416(F)r.2
Lucent Technologies Inc.
25
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
Outline Diagram (continued)
Board Installation Recommendations
0.705
0.193
0.100
0.060
0.100
0.012
0.320
0.311
ø0.032
0.050
0.019685
TYP
0.160
0.941
0.320
0.270
0.050
HEAT SINK
GROUND
PATTERN
0.160
0.270
5-9862 (F)r.1
Figure 12. Heat Sink Ground Pattern
Thermal Considerations (MBIC 025 BiCMOS and MBIC 025 SiGe BiCMOS)
The TRCV012G5 and TRCV012G7 devices use a square heat sink on the bottom of the package for heat dissipation. This heat sink is planar with the lead surface which contacts the board. For optimum heat transfer, the heat
sink should be soldered to the application board using the suggested footprint shown above. Depending on the
application more heat sinking may be required.
Note: Certain precautions must be taken when using solder. For installation using a constant temperature solder,
temperatures of under 300 °C may be employed for periods of time up to 5 seconds, maximum. For installation with a soldering iron (battery operated or non-switching only), the soldering tip temperature should not
be greater than 300 °C and the soldering time for each lead must not exceed 5 seconds.
Table 19. Thermal Resistance
Parameter
Symbol
Conditions
Thermal resistance, junction to board
Thermal resistance, junction to
ambient
θJB
θJA
No air flow, device soldered to board
100 lfpm, device soldered to board
300 lfpm, device soldered to board
500 lfpm, device soldered to board
26
Unit
(°C/W)
11.5
18
15.6
14.6
Lucent Technologies Inc.
Preliminary Data Sheet
August 2000
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Ordering Information
Device Code
TRCV012G5:
TRCV012G5 (BiCMOS)
TRCV012G53XE1 (SiGe BiCMOS)
TRCV012G7:
TRCV012G7 (BiCMOS)
TRCV012G73XE1 (SiGe BiCMOS)
—
Package
Temperature
Comcode
(Ordering Number)
128-pin QFP
128-pin QFP
–40 °C to +85 °C
–40 °C to +85 °C
108419953
108700675
128-pin QFP
128-pin QFP
—
–40 °C to +85 °C
–40 °C to +85 °C
—
108560343
108700683
—
DS00-234HSPL Replaces DS00-154HSPL to Incorporate the Following Updates
1. Added a second technology, MBIC 025 SiGe BiCMOS, to the data sheet.
2. Page 8, REFCLKP/N pins, corrected definition.
3. Page 11, Table 5, updated C1, R1, and R2 values in Clock Recovery Loop Filter Component Values.
4. Page 19, Absolute Maximum Ratings, added maximum power supply value of 4.0 V.
5. Page 19, Handling Precautions, corrected ESD threshold value from TBD to ≥200 V.
6. Page 19, Table 8, corrected BiCMOS power dissipation from TBD to 3.43 W in Recommended Operating Conditions; added MBIC 025 SiGe BiCMOS power dissipation values.
7. Page 19, Table 8, added junction temperature in Recommended Operating Conditions.
8. Page 21, Table 12, corrected values in LVPECL Output Pin Characteristics.
9. Page 23, Table 17, updated minimum duty cycle from 40% to 48%, maximum duty cycle from 60% to 52%, and
tDD1 minimum value from 2.5 ns to 2.9 ns in LVPECL Output Pin ac Timing Characteristics.
10. Page 26, added the section Board Installation Recommendations and Thermal Considerations (MBIC 025
BiCMOS and MBIC 025 SiGe BiCMOS).
11. Page 27, Ordering Information, added MBIC 025 SiGe BiCMOS comcodes.
Lucent Technologies Inc.
27
TRCV012G5 and TRCV012G7
Limiting Amplifier, Clock Recovery, 1:16 Data Demultiplexer
Preliminary Data Sheet
August 2000
For additional information, contact your Microelectronics Group Account Manager or the following:
http://www.lucent.com/micro
INTERNET:
[email protected]
E-MAIL:
N. AMERICA: Microelectronics Group, Lucent Technologies 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 PACIFIC: Microelectronics Group, Lucent Technologies Singapore Pte. Ltd., 77 Science Park Drive, #03-18 Cintech III, Singapore 118256
Tel. (65) 778 8833, FAX (65) 777 7495
CHINA:
Microelectronics Group, Lucent Technologies (China) Co., Ltd., A-F2, 23/F, Zao Fong Universe Building, 1800 Zhong Shan Xi Road, Shanghai
200233 P. R. China Tel. (86) 21 6440 0468, ext. 325, FAX (86) 21 6440 0652
JAPAN:
Microelectronics Group, Lucent Technologies Japan Ltd., 7-18, Higashi-Gotanda 2-chome, Shinagawa-ku, Tokyo 141, Japan
Tel. (81) 3 5421 1600, FAX (81) 3 5421 1700
EUROPE:
Data Requests: MICROELECTRONICS GROUP DATALINE: Tel. (44) 7000 582 368, FAX (44) 1189 328 148
Technical Inquiries: GERMANY: (49) 89 95086 0 (Munich), UNITED KINGDOM: (44) 1344 865 900 (Ascot),
FRANCE: (33) 1 40 83 68 00 (Paris), SWEDEN: (46) 8 594 607 00 (Stockholm), FINLAND: (358) 9 3507670 (Helsinki),
ITALY: (39) 02 6608131 (Milan), SPAIN: (34) 1 807 1441 (Madrid)
Lucent Technologies Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liability is assumed as a result of their use or application. No
rights under any patent accompany the sale of any such product(s) or information.
Copyright © 2000 Lucent Technologies Inc.
All Rights Reserved
August 2000
DS00-234HSPL (Replaces DS00-154HSPL)