AD ADN2873ACPZ-RL

3.3 V, 50 Mbps to 4.25 Gbps,
Single-Loop, Laser Diode Driver
ADN2873
FEATURES
GENERAL DESCRIPTION
SFP/SFF and SFF-8472 MSA compliant
SFP reference design available
50 Mbps to 4.25 Gbps operation
Automatic average power control
Typical 60 ps output rise/fall time
VCSEL, DFB, and FP laser support
Bias current range: from 2 mA to 100 mA
Modulation current range: from 5 mA to 90 mA
Laser fail alarm and automatic laser shutdown (ALS)
Bias and modulation current monitoring
Voltage setpoint control
Resistor setpoint control
3.3 V supply
24-lead 4 mm × 4 mm LFCSP
Pin compatible with ADN2870
Like the ADN2870, the ADN2873 laser diode driver (LDD) is
designed for advanced SFP and SFF modules, using SFF-8472
digital diagnostics. The ADN2873 supports NRZ data
transmission operation from 50 Mbps up to 4.25 Gbps. With a
new alarm scheme, this device avoids the shutdown issue
caused by the system transient generated from various lasers.
APPLICATIONS
The ADN2873 is pin compatible with the ADN2870 dual-loop
LDD, allowing the same design to work with either device. For
dual-loop control applications, refer to the ADN2870 data sheet.
The ADN2873 monitors the laser bias and modulation currents
and it provides fail alarms and ALS. Using setup voltages of a
microcontroller DAC or a trimmable resistor voltage divider,
the ADN2873 can set up a laser optical average output power and
extinction ratio. The optical average power control loop consists
of an optical feedback from a photodiode, the comparator, and a
status holder. The ADN2873 works easily with the Analog
Devices, Inc., ADuC7019/ADuC702x family of MicroConverter®
devices and with the ADN289x family of limiting amplifiers to
make a complete SFP/SFF transceiver chipset solution.
1×/2×/4× Fibre Channel SFP/SFF modules
Multirate OC3 to OC48-FEC SFP/SFF modules
LX-4 modules
DWDM/CWDM laser transmitters
HDTV (SMPTE family) laser transmitters
The product is available in a space-saving 24-lead, 4 mm × 4 mm
LFCSP specified over the −40°C to +85°C temperature range.
Figure 1 shows an application diagram of the voltage setpoint
control with single-ended laser interface. Figure 36 shows a
differential laser interface.
APPLICATIONS DIAGRAM
VCC
VCC
VCC
VCC
L
Tx_DISABLE
Tx_FAULT
FAIL
ALS
IMODN
LASER
R
VCC
IMODP
MPD
DATAP
PAVSET
ANALOG DEVICES
MICROCONTROLLER
PAVREF
DAC
GND
RZ
×100
1kΩ
DAC
VCC
IBIAS
RPAV
ADC
DATAN
100Ω
CONTROL
CCBIAS
IMOD
ERREF
ERSET
ADN2873
1kΩ
GND
IBMON
IMMON
1kΩ
470Ω
PAVCAP
NC
GND
GND
GND
07493-001
VCC GND
Figure 1.
Rev. 0
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2008 Analog Devices, Inc. All rights reserved.
ADN2873
TABLE OF CONTENTS
Features .............................................................................................. 1 Laser Control .............................................................................. 13 Applications ....................................................................................... 1 Control Methods ........................................................................ 13 General Description ......................................................................... 1 Voltage Setpoint Calibration ..................................................... 13 Applications Diagram ...................................................................... 1 Resistor Setpoint Calibration .................................................... 15 Revision History ............................................................................... 2 IMPD Monitoring .......................................................................... 15 Specifications..................................................................................... 3 Loop Bandwidth Selection ........................................................ 16 SFP Timing Specifications........................................................... 5 Power Consumption .................................................................. 16 Absolute Maximum Ratings............................................................ 6 Automatic Laser Shutdown (TX_Disable) .............................. 16 ESD Caution .................................................................................. 6 Bias and Modulation Monitor Currents.................................. 16 Pin Configuration and Function Descriptions ............................. 7 IBIAS Pin ..................................................................................... 16 Typical Performance Characteristics ............................................. 8 Data Inputs .................................................................................. 17 Single-Ended Output ................................................................... 8 Laser Diode Interfacing ............................................................. 17 Differential Output ....................................................................... 9 Alarms.......................................................................................... 18 Performance Characteristics ..................................................... 10 Outline Dimensions ....................................................................... 19 Optical Waveforms ......................................................................... 12 Ordering Guide .......................................................................... 19 Theory of Operation ...................................................................... 13 REVISION HISTORY
6/08—Revision 0: Initial Version
Rev. 0 | Page 2 of 20
ADN2873
SPECIFICATIONS
VCC = 3.0 V to 3.6 V. All specifications TMIN to TMAX1, unless otherwise noted. Typical values are specified at 25°C.
Table 1.
Parameter
LASER BIAS CURRENT (IBIAS)
Output Current IBIAS
Compliance Voltage
IBIAS when ALS Is High
MODULATION CURRENT (IMODP, IMODN)2
Output Current IMOD
Compliance Voltage
IMOD when ALS Is High
Rise Time Single-Ended Output2, 3
Fall Time Single-Ended Output2, 3
Random Jitter Single-Ended Output2, 3
Deterministic Jitter Single-Ended Output3, 4
Pulse Width Distortion2, 3 Single-Ended Output
Rise Time Differential Output3, 5
Fall Time Differential Output3, 5
Random Jitter Differential Output3, 5
Deterministic Jitter Differential Output3, 6
Pulse Width Distortion Differential Output3, 5
Rise Time Differential Output3, 5
Fall Time Differential Output3, 5
Random Jitter Differential Output3, 5
Deterministic Jitter Differential Output3, 7
Pulse Width Distortion Differential Output3, 5
AVERAGE POWER SET (PAVSET)
Pin Capacitance
Voltage
Photodiode Monitor Current (Average Current)
EXTINCTION RATIO SET INPUT (ERSET)
Resistance Range
AVERAGE POWER REFERENCE VOLTAGE INPUT (PAVREF)
Voltage Range
Photodiode Monitor Current (Average Current)
EXTINCTION RATIO REFERENCE VOLTAGE INPUT (ERREF)
Voltage Range
ERREF Voltage to IMOD Gain
DATA INPUTS (DATAP, DATAN)8
Input Voltage Swing (Differential)
Input Impedance (Single-Ended)
LOGIC INPUTS (ALS)
VIH
VIL
ALARM OUTPUT (FAIL)9
VOFF
VON
Min
Typ
Max
Unit
2
1.2
100
VCC
0.1
mA
V
mA
5
1.5
90
VCC
0.1
104
96
1.1
35
30
mA
V
mA
ps
ps
ps (rms)
ps
ps
ps
ps
ps (rms)
ps
ps
ps
ps
ps (rms)
ps
ps
5 mA < IMOD < 90 mA
5 mA < IMOD < 90 mA
5 mA < IMOD < 90 mA
5 mA < IMOD < 90 mA
20 mA < IMOD < 90 mA
20 mA < IMOD < 90 mA
5 mA < IMOD < 30 mA
5 mA < IMOD < 30 mA
5 mA < IMOD < 30 mA
5 mA < IMOD < 30 mA
5 mA < IMOD < 30 mA
5 mA < IMOD < 90 mA
5 mA < IMOD < 90 mA
5 mA < IMOD < 90 mA
5 mA < IMOD < 90 mA
5 mA < IMOD < 90 mA
80
1.3
1200
pF
V
μA
Resistor setpoint mode
25
1.01
kΩ
kΩ
Resistor setpoint mode
Voltage setpoint mode
1
1000
V
μA
Voltage setpoint mode (RPAV fixed at 1 kΩ)
Voltage setpoint mode (RPAV fixed at 1 kΩ)
0.9
V
mA/V
Voltage setpoint mode (RERSET fixed at 1 kΩ)
2.4
V p-p
Ω
AC-coupled
60
60
0.8
19
21
47.1
46
0.64
12
2.1
56
55
0.61
17
1.6
1.1
50
1.5
0.99
1.2
1
0.07
70
0.05
100
0.4
50
2
0.8
V
V
>1.8
V
<1.3
V
Rev. 0 | Page 3 of 20
Conditions/Comments
Voltage required at FAIL for IBIAS and
IMOD to turn off when FAIL asserted
Voltage required at FAIL for IBIAS and
IMOD to stay on when FAIL asserted
ADN2873
Parameter
IBMON, IMMON DIVISION RATIO
IBIAS/IBMON3
IBIAS/IBMON3
IBIAS/IBMON3
IBIAS/IBMON STABILITY3, 10
IMOD/IMMON
IBMON Compliance Voltage
SUPPLY
ICC11
VCC (with Respect to GND)12
Min
Typ
Max
Unit
Conditions/Comments
76
85
92
98
98
100
112
115
108
±5
2 mA < IBIAS < 11 mA
11 mA < IBIAS < 50 mA
50 mA < IBIAS < 100 mA
10 mA < IBIAS < 100 mA
1.3
A/A
A/A
A/A
%
A/A
V
mA
V
When IBIAS = IMOD = 0 mA
3.6
42
0
31
3.3
3.0
1
Temperature range is from −40°C to +85°C.
Measured into a single-ended 15 Ω load (22 Ω resistor in parallel with digital scope 50 Ω input) using a 1111111100000000 pattern at 2.5 Gbps, shown in Figure 2.
Guaranteed by design and characterization. Not production tested.
4
Measured into a single-ended 15 Ω load using a K28.5 pattern at 2.5 Gbps, shown in Figure 2.
5
Measured into a differential 30 Ω (43 Ω differential resistor in parallel with a digital scope of 50 Ω input) load using a 1111111100000000 pattern at 4.25 Gbps, as
shown in Figure 3.
6
Measured into a differential 30 Ω load using a K28.5 pattern at 4.25 Gbps, as shown in Figure 3.
7
Measured into a differential 30 Ω load using a K28.5 pattern at 2.7 Gbps, as shown in Figure 3.
8
When the voltage on DATAP is greater than the voltage on DATAN, the modulation current flows into the IMODP pin.
9
Guaranteed by design. Not production tested.
10
IBIAS/IBMON ratio stability is defined in SFF-8472 Revision 9 over temperature and supply variation.
11
See the ICC minimum for power calculation in the Power Consumption section.
12
All VCC pins should be shorted together.
2
3
ADN2873
R
22Ω
VCC
L
C
IMODP
BIAS TEE
80kHz → 27GHz
TO HIGH SPEED
DIGITAL
OSCILLOSCOPE
50Ω INPUT
07493-002
VCC
Figure 2. High Speed Electrical Test Single-Ended Output Circuit
BIAS TEE
80kHz → 27GHz
VCC
L
C
IMODN
ADN2873
TO HIGH SPEED
DIGITAL
OSCILLOSCOPE
50Ω DIFFERENTIAL INPUT
R
43Ω
IMODP
L
C
BIAS TEE
80kHz → 27GHz
Figure 3. High Speed Electrical Test Differential Output Circuit
Rev. 0 | Page 4 of 20
07493-003
VCC
ADN2873
SFP TIMING SPECIFICATIONS
Table 2.
Parameter
ALS Assert Time
Symbol
t_off
ALS Negate Time1
Time to Initialize, Including Reset of FAIL1
FAIL Assert Time
ALS to Reset Time
Typ
1
Max
5
Unit
μs
t_on
0.15
0.4
ms
t_init
t_fault
t_reset
25
275
100
5
ms
μs
μs
Conditions/Comments
Time for the rising edge of ALS (Tx_DISABLE) to when
the bias current falls below 10% of nominal
Time for the falling edge of ALS to when the modulation
current rises above 90% of nominal
From power-on or negation of FAIL using ALS
Time to fault to FAIL on
Time Tx_DISABLE must be held high to reset Tx_FAULT
Guaranteed by design and characterization. Not production tested.
VSE
DATAP
DATAN
DATAP – DATAN
07493-004
V p-p DIFF = 2 × VSE
0V
Figure 4. Signal Level Definition
SFP MODULE
1µH
VCC_Tx
3.3V
0.1µF
0.1µF
10µF
SFP HOST BOARD
Figure 5. Recommended SFP Supply
Rev. 0 | Page 5 of 20
07493-005
1
Min
ADN2873
ABSOLUTE MAXIMUM RATINGS
Table 3.
Parameter
VCC to GND
IMODN, IMODP
All Other Pins
Junction Temperature
Operating Temperature Range, Industrial
Storage Temperature Range
Junction Temperature (TJ max)
Power Dissipation1
θJA Thermal Impedance2
θJC Thermal Impedance
Lead Temperature (Soldering, 10 sec)
Rating
4.2 V
−0.3 V to +4.8 V
−0.3 to +3.9 V
150°C
−40°C to +85°C
–65°C to +150°C
125°C
(TJ max − TA)/θJA W
30°C/W
29.5°C/W
300°C
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
ESD CAUTION
1
Power consumption equations are provided in the Power Consumption
section.
2
θJA is defined when the part is soldered on a four-layer board.
Rev. 0 | Page 6 of 20
ADN2873
24
23
22
21
20
19
IBIAS
GND
IMODN
IMODP
VCC
GND
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
1
2
3
4
5
6
PIN 1
INDICATOR
ADN2873
TOP VIEW
(Not to Scale)
18
17
16
15
14
13
FAIL
IBMON
VCC
ERREF
IMMON
ERSET
NOTES
1. NC = NO CONNECT.
2. THE LFCSP HAS AN EXPOSED PADDLE THAT MUST BE CONNECTED
TO GND.
07493-006
NC
PAVCAP
GND
DATAP
DATAN
ALS
7
8
9
10
11
12
CCBIAS
PAVSET
GND
VCC
PAVREF
RPAV
Figure 6. Pin Configuration
Table 4. Pin Function Descriptions
Pin No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
Mnemonic
CCBIAS
PAVSET
GND
VCC
PAVREF
RPAV
NC
PAVCAP
GND
DATAP
DATAN
ALS
ERSET
IMMON
ERREF
VCC
IBMON
FAIL
GND
VCC
IMODP
IMODN
GND
IBIAS
Description
Not Used (Internally Connected to VCC)
Average Optical Power Set Pin
Supply Ground
Supply Voltage
Reference Voltage Input for Average Optical Power Control
Average Power Resistor when Using PAVREF
No Connect
Average Power Loop Capacitor
Supply Ground
Data, Positive Differential Input
Data, Negative Differential Input
Automatic Laser Shutdown
Extinction Ratio Set Pin
Modulation Current Monitor Current Source
Reference Voltage Input for Extinction Ratio Control
Supply Voltage
Bias Current Monitor Current Source
FAIL Alarm Output
Supply Ground
Supply Voltage
Modulation Current Positive Output (Current Sink), Connect to Laser Diode
Modulation Current Negative Output (Current Sink)
Supply Ground
Laser Diode Bias (Current Sink to Ground)
Rev. 0 | Page 7 of 20
ADN2873
TYPICAL PERFORMANCE CHARACTERISTICS
SINGLE-ENDED OUTPUT
These performance characteristics were measured using the high speed electrical single-ended output circuit shown in Figure 2.
1.2
90
RANDOM JITTER (rms)
1.0
RISE TIME (ps)
60
30
0.8
0.6
0.4
0
20
40
60
80
100
MODULATION CURRENT (mA)
0
07493-012
0
0
20
40
60
80
100
MODULATION CURRENT (mA)
Figure 7. Rise Time vs. Modulation Current, IIBIAS = 20 mA
07493-014
0.2
Figure 9. Random Jitter vs. Modulation Current, IIBIAS = 20 mA
45
80
DETERMINISTIC JITTER (ps)
40
40
20
35
30
25
20
15
10
0
0
20
40
60
80
MODULATION CURRENT (mA)
Figure 8. Fall Time vs. Modulation Current, IIBIAS = 20 mA
100
0
20
40
60
80
MODULATION CURRENT (mA)
100
07493-015
5
07493-013
FALL TIME (ps)
60
Figure 10. Deterministic Jitter at 2.488 Gbps vs. Modulation Current, IIBIAS = 20 mA
Rev. 0 | Page 8 of 20
ADN2873
DIFFERENTIAL OUTPUT
These performance characteristics were measured using the high speed electrical differential output circuit shown in Figure 3.
90
1.2
RANDOM JITTER (rms)
RISE TIME (ps)
1.0
60
30
0.8
0.6
0.4
0
20
40
60
80
100
MODULATION CURRENT (mA)
0
07493-016
0
0
20
40
60
80
100
MODULATION CURRENT (mA)
07493-018
0.2
Figure 13. Random Jitter vs. Modulation Current, IIBIAS = 20 mA
Figure 11. Rise Time vs. Modulation Current, IIBIAS = 20 mA
80
40
DETERMINISTIC JITTER (ps)
35
40
20
30
25
20
15
10
0
0
20
40
60
80
MODULATION CURRENT (mA)
Figure 12. Fall Time vs. Modulation Current, IIBIAS = 20 mA
100
0
0
20
40
60
MODULATION CURRENT (mA)
80
100
07493-019
5
07493-017
FALL TIME (ps)
60
Figure 14. Deterministic Jitter at 4.25 Gbps vs. Modulation Current, IIBIAS = 20 mA
Rev. 0 | Page 9 of 20
ADN2873
240
40
220
38
100
36
IIBIAS = 90mA
SUPPLY CURRENT (I CC)
180
160
IIBIAS = 40mA
140
120
IIBIAS = 20mA
100
IIBIAS = 10mA
80
32
30
28
26
24
22
60
0
10
20
40
60
80
100
MODULATION CURRENT (mA)
20
07493-020
40
34
Figure 15. Total Supply Current vs. Modulation Current
Total Supply Current = IVCC + IIBIAS + IIMOD
–40
25
07493-023
TOTAL SUPPLY CURRENT (mA)
PERFORMANCE CHARACTERISTICS
85
TEMPERATURE (°C)
Figure 18. Supply Current (ICC) vs. Temperature with ALS Asserted, IIBIAS = 11 mA
120
55
115
50
IIMOD/IIMMON GAIN
105
100
95
45
40
90
35
25
85
TEMPERATURE (°C)
Figure 16. IIBIAS/IIBMON Gain vs. Temperature, IIBIAS = 11 mA
30
–50
–30
–10
10
30
50
70
90
110
TEMPERATURE (°C)
Figure 19. IIMOD/IIMMON Gain vs. Temperature, IIMOD = 30 mA
OC48 PRBS31
DATA TRANSMISSION
t_OFF LESS THAN 1µs
TRANSMISSION
ALS
ALS
t_ON
Figure 20. ALS Negate Time, 50 μs/DIV
Figure 17. ALS Assert Time, 5 μs/DIV
Rev. 0 | Page 10 of 20
07493-024
–40
07493-025
80
07493-021
85
07493-022
IIBIAS/IIBMON GAIN
110
ADN2873
TRANSMISSION ON
FAIL ASSERTED
FAULT FORCED ON PAVSET
07493-027
07493-026
POWER SUPPLY TURNED ON
Figure 22. Time to Initialize, Including Reset, 40 ms/DIV
Figure 21. FAIL Assert Time,1 μs/DIV
Rev. 0 | Page 11 of 20
ADN2873
OPTICAL WAVEFORMS
VCC = 3.3 V and TA = 25°C, unless otherwise noted. Note that there was no change to PAVCAP and ERCAP values when different data
rates were tested. Figure 23, Figure 24, and Figure 25 show multirate performance using the low cost Fabry Perot TOSA NEC NX7315UA;
Figure 26 and Figure 27 show performance over temperature using the DFB TOSA Sumitomo SLT2486.
07493-010
(ACQ LIMIT TEST) WAVEFORMS 1001
07493-007
(ACQ LIMIT TEST) WAVEFORMS 1000
Figure 23. Optical Eye 2.488 Gbps, 65 ps/DIV, PRBS 231 − 1
PAV = −4.5 dBm, ER = 9 dB, Mask Margin 25%
Figure 26. Optical Eye 2.488 Gbps, 65 ps/DIV, PRBS 231 − 1
PAV = 0 dBm, ER = 9 dB, Mask Margin 22%, TA = 25°C
(ACQ LIMIT TEST) WAVEFORMS 1000
07493-011
07493-008
(ACQ LIMIT TEST) WAVEFORMS 1001
Figure 27. Optical Eye 2.488 Gbps, 65 ps/DIV, PRBS 231 − 1
PAV = −0.2 dBm, ER = 8.96 dB, Mask Margin 21%, TA = 85°C
Figure 24. Optical Eye 622 Mbps, 264 ps/DIV, PRBS 231 − 1
PAV = −4.5 dBm, ER = 9 dB, Mask Margin 50%
07493-009
(ACQ LIMIT TEST) WAVEFORMS 1000
Figure 25. Optical Eye 155 Mbps,1.078 ns/DIV, PRBS 231 − 1
PAV = −4.5 dBm, ER = 9 dB, Mask Margin 50%
Rev. 0 | Page 12 of 20
ADN2873
THEORY OF OPERATION
Laser diodes have a current-in to light-out transfer function, as
shown in Figure 28. Two key characteristics of this transfer
function are the threshold current, ITH, and the laser slope in the
linear region beyond the threshold current, referred to as the
slope efficiency, LI.
P1
PO
P1 + PO
PAV =
2
P1
ΔP
PAV
ΔI
LI =
PO
ITH
The ADN2873 has two methods for setting the average power
(PAV) and ER. The laser optical output average power and
extinction ratio are configurable by using the voltage setting or
the resistor setting. In voltage setting mode, a microcontroller
DAC can drive the PAVREF and ERREF pins with programmable
voltages. Alternatively, in resistor setting mode, the resistor
divider or potentiometers can set proper voltages at the PAVSET
and ERSET pins. Refer to Figure 29 and Figure 30 for details.
VOLTAGE SETPOINT CALIBRATION
CURRENT
The ADN2873 allows interface to a microcontroller for both
control and monitoring (see Figure 29). The average power and
extinction ratio can be set using the microcontroller DACs to
provide controlled reference voltages, PAVREF and ERREF.
ΔP
ΔI
07493-028
OPTICAL POWER
ER =
CONTROL METHODS
Figure 28. Laser Transfer Function
PAVREF = PAV × RSP × RPAV
LASER CONTROL
ERREF =
I MOD × R ERSET
100
(V)
(V)
Typically, laser threshold current and slope efficiency are both
functions of temperature. For FP-type and/or DFB-type lasers,
the threshold current increases and the slope efficiency decreases
with increasing temperature. In addition, these parameters vary
as the laser ages. To maintain a constant optical average power
and a constant optical extinction ratio over temperature and
laser lifetime, it is necessary to vary the applied electrical bias
current and modulation current to compensate for the changing
LI characteristics of the laser.
In voltage setpoint mode, RPAV and RERSET must be 1 kΩ resistors
with a 1% tolerance and a temperature coefficient of 50 ppm/°C.
Average Power Control Loop (APCL)
Power-On Sequence in Voltage Setpoint Mode
The APCL compensates for changes in ITH and LI by varying
IBIAS. Average power control is performed by measuring the
monitor photodiode (MPD) current, IMPD. This current is
bandwidth limited by the MPD. This is not a problem because
the APCL is required to respond to the average current from the
MPD.
During power-up, an initial sequence allows 25 ms before
enabling the alarms. Therefore, the user must ensure that the
voltages applied to PAVREF and ERREF are stabilized within
20 ms after ramp-up of the power supply. If supplying the
PAVREF and ERREF voltages after the 25 ms, the alarms and
FAIL circuitry kick in before the voltages are stabilized to
PAVREF and ERREF, which causes an unexpected failure.
Extinction Ratio (ER) Control
where:
PAV is the laser optical average power output required.
RSP is the optical responsivity (in amperes per watt).
RPAV = RERSET = 1 kΩ.
IMOD is the modulation current.
ER control is implemented by adjusting the modulation current.
Temperature calibration is required to adjust the modulation
current to compensate for variations of the laser characteristics
with temperature.
Rev. 0 | Page 13 of 20
ADN2873
VCC
VCC
VCC
Tx_DISABLE
VCC
L
Tx_FAULT
VCC
FAIL
ALS
IMODN
LASER
R
MPD
IMODP
DATAP
ANALOG DEVICES
MICROCONTROLLER
PAVSET
PAVREF
DAC
DATAN
100Ω
CONTROL
VCC
IBIAS
RPAV
ADC
×100
1kΩ
CCBIAS
IMOD
GND ERREF
DAC
RZ
ERSET
ADN2873
1kΩ
GND
IBMON
IMMON
VCC GND
PAVCAP
NC
GND
470Ω
07493-029
1kΩ
GND
GND
Figure 29. Using Microconverter Voltage Setpoint Calibration and Monitoring
VCC
VCC
VCC
VCC
L
FAIL
VCC
ALS
IMODN
LASER
R
VCC
IMODP
PAVREF
DATAP
MPD
RPAV
PAVSET
DATAN
100Ω
CONTROL
VCC
IBIAS
GND
VCC
RZ
×100
ERREF
CCBIAS
IMOD
VREF
ERSET
ADN2873
IBMON
VCC GND
1kΩ
GND
IMMON
470Ω
PAVCAP
NC
GND
GND
Figure 30. Using Resistor Setpoint Calibration of Average Power and Extinction Ratio
Rev. 0 | Page 14 of 20
07493-030
GND
ADN2873
RESISTOR SETPOINT CALIBRATION
Method 2: Measuring IMPD Across a Sense Resistor
In resistor setpoint calibration, the PAVREF, ERREF, and RPAV
pins must all be tied to VCC. The average power and extinction
ratio can be set using the PAVSET and ERSET pins, respectively.
A resistor is placed between the pin and GND to set the current
flowing in each pin, as shown in Figure 30. The ADN2873
ensures that both PAVSET and ERSET are kept 1.23 V above
GND. The PAVSET and ERSET resistors are given by
The second method has the advantage of providing a valid IMPD
reading at all times but has the disadvantage of requiring a
differential measurement across a sense resistor directly in
series with the IMPD. As shown in Figure 32, a small resistor, Rx,
is placed in series with the IMPD. If the laser used in the design
has a pinout where the monitor photodiode cathode and the
lasers anode are not connected, a sense resistor, Rx, can be placed
in series with the photodiode cathode and VCC, as shown in
Figure 33. When choosing the value of the resistor, the user must
take into account the expected IMPD value in normal operation.
The resistor must be large enough to make a significant signal
for the buffered ADC to read, but small enough not to cause a
significant voltage reduction across the photodiode. The voltage
across the sense resistor should not exceed 250 mV when the
laser is in normal operation. It is recommended that a 10 pF
capacitor be placed in parallel with the sense resistor.
(kΩ)
1.2 V × 100
(kΩ)
IMOD
where:
PAV is the average power required (mW).RSP is the optical
responsivity (in mA/mW).
IMOD is the modulation current required (mA).
VCC
Power-On Sequence in Resistor Setpoint Mode
Note that during power-up, the ADN2873 starts an initial process
sequence that allows 25 ms before enabling the device alarms.
The resistors connected to the PAVSET and ERSET pins should
be stable within 20 ms after turning on the power supply. The
ADN2873 alarm may kick in and assert FAIL, provided the
PAVSET and ERSET resistors are stabilized 20 ms after turning
on the power supply.
PHOTODIODE
MICROCONVERTER
ADC DIFFERENTIAL
INPUT
10pF
ADN2873
Figure 32. Differential Measurement of IMPD Across a Sense Resistor
IMPD monitoring can be implemented for voltage setpoint and
resistor setpoint as described in the following sections.
VCC
Voltage Setpoint
In voltage setpoint calibration, two methods can be used for
IMPD monitoring: measuring voltage at RPAV and measuring
IMPD across a sense resistor.
MICROCONVERTER
ADC
INPUT
200Ω
Rx
VCC
LD
PHOTODIODE
Method 1: Measuring Voltage at RPAV
PAVSET
The IMPD current is equal to the voltage at RPAV divided by the
value of RPAV (see Figure 31) as long as the laser is on and is
being controlled by the control loop. This method does not
provide a valid IMPD reading when the laser is in shutdown or fail
mode. A microconverter-buffered ADC input can be connected to
RPAV to make this measurement. No decoupling or filter capacitors should be placed on the RPAV node because this can disturb
the control loop.
VCC
PHOTODIODE
PAVSET
ADN2873
ADN2873
Figure 33. Single Measurement of IMPD Across a Sense Resistor
Resistor Setpoint
In resistor setpoint calibration, the current through the resistor
from PAVSET to GND is the IMPD current. The recommended
method for measuring the IMPD current is to place a small resistor in series with the PAVSET resistor (or potentiometer) and
measure the voltage across this resistor, as shown in Figure 34. The
IMPD current is then equal to this voltage divided by the value of
resistor used. In resistor setpoint calibration, PAVSET is held to
1.2 V nominal; it is recommended that the sense resistor be
selected so that the voltage across the sense resistor does not
exceed 250 mV.
07493-031
RPAV
R
1kΩ
200Ω
Rx
PAVSET
IMPD MONITORING
MICROCONVERTER
ADC
INPUT
LD
07493-032
RERSET =
1.2 V
PAV × RSP
07493-033
R PAVSET =
Figure 31. Single Measurement of IMPD at RPAV in Voltage Setpoint Mode
Rev. 0 | Page 15 of 20
ADN2873
VCC
Power consumption can be calculated as
PHOTODIODE
ICC = ICC min + 0.3 IMOD
P = VCC × ICC + (IBIAS × VBIAS_PIN) + IMOD (VMODP_PIN + VMODN_PIN)/2
PAVSET
ADN2873
R
TDIE = TAMBIENT + θJA × P
07493-034
MICROCONVERTER
ADC
INPUT
Figure 34. Recommended Method of IMPD Measurement Across a
Sense Resistor in Resistor Setting Mode
LOOP BANDWIDTH SELECTION
To ensure that the ADN2873 control loop has sufficient
bandwidth, the average power loop capacitor (PAVCAP) is
calculated using the slope efficiency of the laser (watts/amps)
and the average power required.
For resistor setpoint control,
PAVCAP = 3.2 × 10 −6 ×
LI
PAV
(Farad)
For voltage setpoint control,
PAVCAP = 1.28 × 10 −6 ×
LI
PAV
(Farad)
where:
LI is the typical slope efficiency at 25°C of a batch of lasers that
PAV is the average power required (mW).
are used in a design (mW/mA).
LI can be calculated as
LI =
P1 − P0
I
MOD
(mW/mA)
where:
P1 is the optical power (mW) at the one level.
P0 is the optical power (mW) at the zero level.
Thus, the maximum combination of IBIAS + IMOD must be
calculated, where:
ICC min = 32 mA, the typical value of ICC provided in Table 1
with IBIAS = IMOD = 0.
TDIE is the die temperature.
VBIAS_PIN is the voltage at the IBIAS pin.
VMODP_PIN is the voltage at the IMODP pin.
VMODN_PIN is the voltage at the IMODN pin.
TAMBIENT is the ambient temperature.
AUTOMATIC LASER SHUTDOWN (TX_DISABLE)
ALS (TX_DISABLE) is an input that is used to shut down the
optical output of the transmitter. The ALS pin is pulled up
internally with a 6 kΩ resistor and conforms to SFP MSA
specifications. When ALS is logic high or when open, both the
bias and modulation currents are turned off. If an alarm has
been triggered and the bias and modulation currents are turned
off, ALS can be brought high and then low to clear the alarm.
BIAS AND MODULATION MONITOR CURRENTS
IBMON and IMMON are current-controlled current sources
that mirror a ratio of the bias and modulation current. The
monitor bias current, IBMON, and the monitor modulation
current, IMMON, should both be connected to ground through
a resistor to provide a voltage proportional to the bias current
and modulation current, respectively. When using a microcontroller, the voltage developed across these resistors can be
connected to two of the ADC channels, making a digital
representation of the bias and modulation current available.
IBIAS PIN
The capacitor value equation is used to obtain a centered value
for the particular type of laser that is used in a design and an
average power setting. The laser LI can vary by a factor of 7
between different physical lasers of the same type and across
temperatures without the need to recalculate the PAVCAP value.
This capacitor is placed between the PAVCAP pin and ground.
It is important that the capacitor is a low leakage, multilayer
ceramic type with an insulation resistance greater than 100 GΩ
or a time constant of 1000 sec, whichever is less. Pick a standard
off-the-shelf capacitor value such that the actual capacitance is
within ±30% of the calculated value after the capacitor’s own
tolerance is taken into account.
POWER CONSUMPTION
The ADN2873 die temperature must be kept below 125°C. The
LFCSP has an exposed paddle, which should be connected so
that it is at the same potential as the ADN2873 GND pins.
The ADN2873 IBIAS pin has one on-chip, 800 Ω pull-up resistor.
The current sink from this resistor is VIBIAS dependent.
I UP =
VCC − V IBIAS
0. 8
(mA)
where VIBIAS is the voltage measured at the IBIAS pin after setup
of one laser bias current, IBIAS.
Usually, when set up, a maximum laser bias current of 100 mA
results in a VIBIAS to about 1.2 V. In a worst-case scenario, VCC =
3.6 V, VIBIAS = 1.2 V, and IUP (the current bypass through the 800 Ω
resistor) ≤ 3 mA.
This on-chip resistor damps out the low frequency oscillation
observed from some inexpensive lasers. If the on-chip resistance
does not provide enough damping, one external RZ (see Figure 35)
may be necessary.
Rev. 0 | Page 16 of 20
ADN2873
transmission line values can be used, with some modification of
the component values. In Figure 35, the R and C snubber values
24 Ω and 2.2 pF, respectively, represent a starting point and must
be tuned for the particular model of laser being used. RP, the
pull-up resistor, is in series with a very small (0.5 nH) inductor.
In some cases, an inductor is not required or can be accommodated with deliberate parasitic inductance, such as a thin trace
or a via placed on the PC board.
DATA INPUTS
Data inputs should be ac-coupled (10 nF capacitors are recommended) and are terminated via a 100 Ω internal resistor between
the DATAP and DATAN pins. A high impedance circuit sets the
common-mode voltage and is designed to allow maximum
input voltage headroom over temperature. It is necessary to use
ac-coupling to eliminate the need for matching the common-mode
voltages of the data source and the ADN2873 data input pins.
Care should be taken to mount the laser as close as possible to
the PC board, minimizing the exposed lead length between the
laser can and the edge of the board. The axial lead of a coax
laser is very inductive (approximately 1 nH per mm). Long
exposed leads result in slower edge rates and reduced eye margin.
LASER DIODE INTERFACING
Figure 35 shows the recommended circuit for interfacing the
ADN2873 to most TO-can or coax lasers. Uncooled DFB and
FP lasers typically have impedances of 5 Ω to 7 Ω and have axial
leads. The circuit shown works over the full range of data rates
from 155 Mbps to 3.3 Gbps, including multirate operation (without
changes to PAVCAP and ERCAP values); see Figure 23, Figure 24,
and Figure 25 for multirate performance examples. Coax lasers
have special characteristics that make them difficult to interface to.
They tend to have higher inductance and their impedance is not
well controlled. The circuit in Figure 35 operates by deliberately
misterminating the transmission line at the laser side while providing a very high quality matching network at the driver side.
Recommended component layouts and Gerber files are available
by contacting sales at Analog Devices. Note that the circuit in
Figure 35 can supply up to 56 mA of modulation current to the
laser, sufficient for most lasers available today. Higher currents
can be accommodated by changing transmission lines and backmatch values; contact sales for recommendations. This interface
circuit is not recommended for butterfly-style lasers or other lasers
with 25 Ω characteristic impedance. Instead, a 25 Ω transmission
line and inductive (instead of resistive) pull-up is recommended.
The ADN2873 single-ended application shown in Figure 35 is
recommended for use up to 2.7 Gbps. From 2.7 Gbps to 4.25 Gbps,
a differential drive is recommended when driving VCSELs or lasers
that have slow fall times. Differential drive can be implemented by
adding a few extra components. A possible implementation is
shown in Figure 36. The bias and modulation currents that are
programmed into the ADN2873 need to be larger than the bias
and modulation current required at the laser due to the laser ac
coupling interface and because some modulation current flows
in the pull-up resistors, R1 and R2.
The impedance of the driver side matching network is very flat
in the designed frequency range and enables multirate operation.
A series damping resistor should not be used.
VCC
L (0.5nH)
VCC
C
100nF
IMODP
Tx LINE
30Ω
RZ
IBIAS
Tx LINE
30Ω
VCC
R
24Ω
C
2.2pF
L
07493-035
ADN2873
BLM18HG601SN1D
In Figure 35 and Figure 36, Resistor RZ is required to achieve
optimum eye quality. The recommended RZ value is approximately
500 Ω ~ 800 Ω.
Figure 35. Recommended Interface for ADN2873 AC Coupling
The 30 Ω transmission line used is a compromise between the
drive current required and the total power consumed. Other
The interface circuit needs a special modification to support
HDTV pathological test patterns. Contact sales at Analog Devices
for HDTV support.
VCC
L4 = BLM18HG601SN1D
L1 = 0.5nH
R1 = 15Ω
C1 = C2 = 100nF
L3 = 4.7nH
TO-CAN/VCSEL
IMODN
20Ω TRANSMISSION LINES R3
ADN2873
C3
SNUBBER
LIGHT
IMODP
IBIAS
R2 = 15Ω
L2 = 0.5nH
L6 = BLM18HG601SN1D
VCC
VCC
RZ
SNUBBER SETTINGS: 40Ω AND 1.5pF, NOT OPTIMIZED, OPTIMIZATION SHOULD
CONSIDER THE PARASITIC OF THE INTERFACE CIRCUITRY.
Figure 36. Recommended Differential Drive Circuit
Rev. 0 | Page 17 of 20
07493-036
RP
24Ω
ADN2873
The ADN2873 has a latched, active high monitoring alarm
(FAIL). The FAIL alarm output is open drain in conformance
with SFP MSA specification requirements.
The ADN2873 has a three-fold alarm system that covers
•
•
•
Use of a bias current that is higher than expected, likely as
a result of laser aging
Out-of-bounds average voltage at the monitor photodiode
(MPD) input, indicating an excessive amount of laser
power or a broken loop
Undervoltage in the IBIAS node (laser diode cathode) that
would increase the laser power
activated when the single-point alarms in Table 5 occur. The
circuit in Figure 37 can be used to indicate that FAIL has been
activated while allowing the bias and modulation currents to
remain on. The VBE of the transistor clamps the FAIL voltage to
below 1.3 V, disabling the automatic shutdown of bias and modulation currents. If an alarm has triggered and FAIL is activated,
ALS can be brought high and then low to clear the alarm.
The bias current alarm trip point is set by selecting the value
of resistor on the IBMON pin to GND. The alarm is triggered
when the voltage on the IBMON pin goes above 1.2 V. FAIL is
VCC
LED
D1
R1
10kΩ
FAIL
R2
330Ω
Q1
NPN
ADN2873
07493-037
ALARMS
Figure 37. FAIL Indication Circuit
Table 5. ADN2873 Single-Point Alarms
Alarm Type
Bias Current
MPD Current
Crucial
Nodes
Mnemonic
IBMON
PAVSET
ERREF (the ERRREF designed is tied
to VCC in resistor setting mode)
IBIAS
Overvoltage or Short to VCC Condition
Alarm if >1.2 V typical (±10% tolerance)
Alarm if >2.0 V
Alarm if shorted to VCC (the alarm is
valid for voltage setting mode only)
Ignore
Undervoltage or Short to GND Condition
Ignore
Alarm if <0. 4V
Ignore
Alarm if shorted to GND
Table 6. ADN2873 Response to Various Single-Point Faults in AC-Coupled Configuration (as shown in Figure 35 and Figure 36)
Pin
PAVSET
PAVREF
Short to VCC
Fault state occurs
Voltage mode: fault state occurs
Resistor mode: tied to VCC
Short to GND
Fault state occurs
Fault state occurs
RPAV
Voltage mode: fault state occurs
Resistor mode: tied to VCC
Fault state occurs
PAVCAP
DATAP
DATAN
ALS
ERSET
IMMON
ERREF
Fault state occurs
Does not increase laser average power
Does not increase laser average power
Output currents shut off
Does not increase laser average power
Does not affect laser power
Voltage mode: fault state occurs
IBMON
FAIL
IMODP
IMODN
IBIAS
Resistor mode: tied to VCC
Fault state occurs
Fault state occurs
Does not increase laser average power
Does not increase laser average power
Fault state occurs
Fault state occurs
Does not increase laser average power
Does not increase laser average power
Normal currents
Does not increase laser average power
Does not increase laser average power
Voltage mode: does not increase average
power
Resistor mode: fault state occurs
Does not increase laser average power
Does not increase laser average power
Does not increase laser average power
Does not increase laser average power
Fault state occurs
Rev. 0 | Page 18 of 20
Open
Fault state occurs
Fault state occurs
Circuit designed to tie to VCC in resistor
setting mode, so no open case
Voltage mode: fault state occurs
Resistor mode: does not increase
average power
Fault state occurs
Does not increase laser average power
Does not increase laser average power
Output currents shut off
Does not increase laser average power
Does not increase laser average power
Does not increase laser average power
Does not increase laser average power
Does not increase laser average power
Does not increase laser average power
Does not increase laser power
Fault state occurs
ADN2873
OUTLINE DIMENSIONS
0.60 MAX
4.00
BSC SQ
PIN 1
INDICATOR
0.60 MAX
TOP
VIEW
0.50
BSC
3.75
BSC SQ
0.50
0.40
0.30
1.00
0.85
0.80
12° MAX
SEATING
PLANE
0.80 MAX
0.65 TYP
0.30
0.23
0.18
PIN 1
INDICATOR
19
18
24 1
*2.45
2.30 SQ
2.15
EXPOSED
PAD
(BOTTOMVIEW)
13
12
7
6
0.23 MIN
2.50 REF
0.05 MAX
0.02 NOM
0.20 REF
COPLANARITY
0.08
*COMPLIANT TO JEDEC STANDARDS MO-220-VGGD-2
EXCEPT FOR EXPOSED PAD DIMENSION
Figure 38. 24-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
4 mm × 4 mm Body, Very Thin Quad
(CP-24-2)
Dimensions shown in millimeters
ORDERING GUIDE
Model
ADN2873ACPZ1
ADN2873ACPZ-RL1
ADN2873ACPZ-RL71
1
Temperature Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Package Description
24-Lead Lead Frame Chip Scale Package (LFCSP_VQ)
24-Lead Lead Frame Chip Scale Package (LFCSP_VQ)
24-Lead Lead Frame Chip Scale Package (LFCSP_VQ)
Z = RoHS Compliant Part.
Rev. 0 | Page 19 of 20
Package Option
CP-24-2
CP-24-2
CP-24-2
ADN2873
NOTES
©2008 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D07493-0-6/08(0)
Rev. 0 | Page 20 of 20