Application Note, Rev. 1
November 2000
Laser Control Circuits for A1611A/B Laser Modules and
the 3641-Type Laser Transmitter Subassembly
Incorporating the A1611A/B laser module, the 3641-type trans-
mitter subassembly (shown below) provides significant advan-
tages for OEMs, system integrators, and end users by enabling
the optimization of transmitter performance in various cable
television environments.
Introduction
The 3641-type laser transmitter engines and
A1611A/B laser modules are the RF/optical hearts
of broadband AM fiber-optic transmitter systems.
Successfully integrating these models into a full
transmitter requires the appropriate set of dc inter-
face circuits.
The information offered here provides an overview of
the two dc circuits needed to successfully drive
these two devices. These are the optical power con-
trol circuit and the temperature control circuit.
Conceptual schematic diagrams of a laser control
circuit, temperature control, and laser module pinout
are shown in Figures 1, 2, and 3, respectively, in the
following pages.
Optical Power Control Circuit
The following paragraphs refer to Figure 1. In order
for a transmitter to perform correctly, it is necessary
to precisely control the optical output power of the
laser. This section describes how this can be done.
In theory, the output of a laser is determined by the
amount of bias current. The goal of an optical power
control circuit, therefore, is to maintain the bias cur-
rent at the proper level.
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Application Note, Rev. 1
November 2000
the 3641-Type Laser Transmitter Subassembly
Laser Control Circuits for A1611A/B Laser Modules and
Optical Power Control Circuit (continued)
One way to do this is to sample the output power of the
laser and use a closed-loop feedback circuit to control
the bias current, and, as a result, the output power.
The monitor photodiode inside the laser package is
used to sample the output power. The back-facet light
from the laser, which is proportional to the power cou-
pled into the fiber, illuminates the monitor photodiode
and generates a current. This current is used as the
sampling element for the feedback control loop, which
keeps the laser power output constant.
The transimpedance amplifier (U1A) converts the mon-
itor photodiode current to a voltage. R3, CR1, and VR1
are used to generate an adjustable reference voltage.
The integrated amplifier (U1B) compares the reference
voltage with the monitor voltage, and outputs the differ-
ence voltage. A voltage-to-current converter, formed by
U1C, Q1, and resistors R5—R10, supplies the laser
with a negative bias. The integrating amplifier adjusts
the negative bias current so that the monitor voltage
equals the reference voltage.
Understanding the Interface Requirements
Photodiode Monitor (Pins 4 and 5). Pin 5 connects to
the cathode of the monitor photodiode in the laser
package. The current drawn by this pin is typically
between 100 µA and 1800 µA when the laser is at its
specified output power. The monitor photodiode should
be biased at 5 V. Pin 4 is connected to signal ground.
The correct operating photodiode current (PDI) is
recorded on the test data sheet provided with the laser
module or the transmitter board. Assuming the above
circuit is used, the monitor photocurrent generates a
voltage between 0.1 V and 1.8 V. Knowing the proper
PDI, the user would adjust the potentiometer VR1 to
obtain the current listed on the factory data sheet.
Laser Bias Current (Pin 3). The maximum current
required by the laser is 120 mA. At this current, the
voltage required (called the compliance voltage) is less
than or equal to –5 V. Therefore, the circuit driving this
pin must be capable of providing 120 mA at –5 V. An
analysis of the circuit shows that at 120 µA, there is a
–1.2 V drop across R9, leaving –1.8 V across transistor
Q1, which is sufficient to drive the laser current.
The operating laser bias current is recorded at the fac-
tory on the test data sheet. If the bias control circuit is
set up properly, the laser bias current and the PDI will
match the values recorded on the test data sheet.
Since the laser bias signal is connected to the laser,
noise or ripple will affect the laser optical output.
Bypass capacitors and series inductors installed on the
laser board attenuate high-frequency noise and ripple,
but low-frequency disturbances can be an issue. The
noise and ripple below 20 MHz should be kept below
50 µA peak-to-peak. This should be taken into account
in the design of the optical power control circuit.
Figure 1. Conceptual Laser Control Circuit Diagram
Agere Systems Inc. 3
Application Note, Rev. 1
November 2000 the 3641-Type Laser Transmitter Subassembly
Laser Control Circuits for A1611A/B Laser Modules and
Optical Power Control Circuit (continued)
Optical Power Status Monitoring
IfacircuitsuchasthatshowninFigure1isusedfor
optical power control, there are two voltages that can
be used to monitor the status of the transmitter.
The voltage at the output of U1A is proportional to the
output power of the laser. If a noninverting amplifier is
connected to this voltage, it can be used to provide a
scaled reading of the optical output power. The scaled
monitor can be used to drive analog test points, as well
as A/D converters for digital status monitoring, or com-
parators for triggering alarm circuits.
Since the laser bias current generates the voltage
across R9, this voltage can be used as a laser bias cur-
rent monitor. Like the optical power monitor voltage, it
can be used for a variety of status monitoring functions.
Verification Tests
Once a power control circuit is designed, it should be
tested to verify that it is working properly. The optical
power control circuit can be assumed to be working
when the optical output power is stable, and the bias
current is the same as the value recorded on the test
data sheet supplied with the laser board. If there is no
resistor in series between the bias control circuit and
the laser board, the bias current can be measured by
either inserting an ammeter between the bias control
circuit and the laser board bias pin, or by installing
a small sense resistor and measuring the voltage
across it.
As a further test, the reference voltage can be varied.
As it is varied, both the optical output from the laser
and the voltage at pin 6 (LSR-1) of the laser board
should be monitored. Any discontinuities in either the
voltage or the output power indicate problems with
the control circuitry.
The power control circuit should be tested over the full
possible range; that is, at PDI values between 100 µA
and 1800 µA.
44 Agere Systems Inc.
Application Note, Rev. 1
November 2000
the 3641-Type Laser Transmitter Subassembly
Laser Control Circuits for A1611A/B Laser Modules and
Temperature Control Circuit
The following paragraphs refer to Figure 2. The chip
temperature of the laser diode is a critical factor. It is
necessary to keep the chip operating at a fixed temper-
ature, usually 25 °C. The laser package is equipped
with devices that make temperature control possible.
The circuits required to do this are described here.
In theory, similar to the optical power control loop, a
feedback circuit is used to keep the laser chip tempera-
ture constant. The chip temperature is controlled with a
thermoelectric cooler (TEC) inside the laser package.
Positive current through the TEC pumps heat from the
laser chip to the laser package. The laser package
must be attached to a heat sink to further reduce the
laser temperature. Conversely, negative current
through the TEC moves heat from the laser package to
the laser chip, resulting in laser heating.
If a bidirectional current source is used, the laser chip
can be heated or cooled, which thereby enables laser
operation in various ambient environments.
To maintain constant laser chip temperature, a feed-
back element is necessary so that the control circuit
can sense the laser chip temperature. For this purpose,
a thermistor is mounted inside the laser package, very
close to the laser chip. Since a thermistor is a tempera-
ture-dependent resistor, a circuit that measures its
resistance is used to sense the chip temperature. The
control circuit then adjusts the TEC current to maintain
the proper laser chip temperature.
A schematic diagram of a conceptual temperature con-
trol circuit is shown below in Figure 2.
R1, 2, 6, 7, CR1, and U1C are used to generate refer-
ence voltages used in other parts of the circuit. R2 and
the laser thermistor form a voltage divider. This voltage
is buffered by U1A and compared to the reference volt-
age at the + terminal of U1B. The reference voltage is
generated by the voltage divider consisting of R3 and
R5. The difference between the reference voltage and
the buffered thermistor voltage is used to drive the inte-
grating amplifier U1B. The output of U1B drives a bipo-
lar voltage-to-current converter U2A, which is a high-
power op amp. The voltage at the output of U2B is con-
trolled so that the full range of TEC current can be sup-
plied without running into the 5 V or ground rails of the
op amp.
Since the integrating amplifier acts to drive the TEC
voltage (between pins 6 and 7), this dictates the maxi-
mum voltage (compliance voltage) between the TEC+
and TEC– pins that can be expected during operation.
It is specified at ±1.9 V. Therefore, the designer must
ensure that the TEC drive circuit can supply the
required current at up to ±1.9 V between its inputs to
zero. The overall circuit drives the thermistor resistance
to equal the resistance of R5. Since the specified chip
temperature is usually 10 kΩ,R5canusuallybeafixed
10 kΩresistor. However, if the user wants to be able to
change the operating temperature of the laser, then an
adjustable resistor could be used in place of R5.
Figure 2. Conceptual Temperature Control Circuit Diagram
Agere Systems Inc. 5
Application Note, Rev. 1
November 2000 the 3641-Type Laser Transmitter Subassembly
Laser Control Circuits for A1611A/B Laser Modules and
Temperature Control Circuit (continued)
Understanding the Interface Requirements
Thermistor (Pins 1 and 2). In addition to resistance,
there is one other important parameter: the tempera-
ture coefficient of resistance. The temperature coeffi-
cient dictates the temperature dependence of the
thermistor. It is typically –4.4% per °C. This means that
if the chip temperature drops from 25 °C to 24 °C, the
nominal thermistor resistance will increase from 10 kΩ
to 10.44 kΩ. Pin 1 is connected to temperature circuit
and Pin 2 is connected to signal ground.
Themoelectric Cooler (Pins 6 and 7). The TEC in the
laser package is connected to pins 6 (TEC +) and 7
(TEC–). When current flows from pin 6, through the
laser package, and out pin 7, heat is pumped from the
laser chip to the laser package, cooling the laser chip. If
current flows in the opposite direction, heat is pumped
from the laser package to the laser chip, heating the
laser chip.
Themoelectric Cooler Current (Between Pins 6
and 7). This specifies the maximum current required to
maintain the laser chip temperature. It is specified at
1.0 A at the minimum laser case temperature of –20 °C
and at 1.5 A at the maximum laser case temperature of
+65 °C. Therefore, the design of the TEC driver must
ensure that driver is capable of supplying this amount
of current.
Themoelectric Cooler Voltage (Between Pins 6
and 7). This indicates the maximum voltage (compli-
ance voltage) between the TEC+ and TEC– pins that
can be expected during operation. It is specified at
±1.9 V. Therefore, the designer must ensure that the
TEC drive circuit can supply the required current at up
to ±1.9 V. The polarity of the voltage depends on
whether the laser is being heated or cooled.
Temperature Status Monitoring
If a circuit such as that shown in Figure 2 is used for
temperature control, there are two voltages that can be
used to monitor the status of the transmitter.
The voltage at the output of U1A is related to the actual
temperature of the laser chip. Since the temperature
coefficient of the thermistor is known, this voltage can
be compared to the nominal voltage, allowing a calcu-
lation of the chip temperature. For example, in the Fig-
ure 2 circuit, a monitor voltage of 1.22 V implies
thermistor resistance of 9.56 kΩ. Since the tempera-
ture coefficient is –4.4% per °C, the laser temperature
in this case would be 26 °C. Similar to the optical power
monitor voltage discussed above, the chip temperature
monitor voltage can be connected to a variety of cir-
cuits a variety of status-monitoring functions.
Another possible parameter to monitor is the TE cooler
current. Since the voltage across R14 is directly gener-
ated by the TE current, this voltage can be used as a
current monitor. This can be particularly useful to indi-
cate when the transmitter temperature is approaching
its limit; a high TEC current (approaching the maxi-
mum) indicates that the laser temperature is close to its
maximum, which could mean that the transmitter tem-
perature is nearly out of range.
Verification Tests
This section describes a simple test that can be used to
make sure a temperature control circuit is operating
properly. The temperature control circuitry can be
assumed to be working when the thermistor resistance
is correct (generally 10 kΩ). Therefore, a method that
directly measures the thermistor resistance, without
disrupting circuit operation, would suffice. This can be
accomplished by inserting an ammeter between the
TEC control circuit and the thermistor pin on the laser
board, and a voltmeter from the thermistor pin to
ground.
The thermistor resistance is simply the measured ther-
mistor voltage divided by the measured thermistor cur-
rent. This setup can be used as the laser package
temperature is changed over its range. A properly
working temperature controller maintains a constant
thermistor resistance as the laser package temperature
is changed over its full temperature range.
Agere Systems 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.
Copyright © 2001 Agere Systems Inc.
All Rights Reserved
November 2000
AP00-067OPTO-1 (Replaces AP00-067OPTO)
For additional information, contact your Agere Systems Account Manager or the following:
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Application Note, Rev. 1
November 2000
the 3641-Type Laser Transmitter Subassembly
Laser Control Circuits for A1611A/B Laser Modules and
Pin Information
Figure 3. A1611A/B Laser Module Pinouts
Table 1. Pin Descriptions
Pin Function
1 Thermistor
2 Thermistor
3 dc Laser Bias (–)
4 MPD Anode, Case Ground
5 MPD Cathode
6TEC(+)
7TEC(–)
8 Case Ground
9 Case Ground
10 NC
11 Laser Common (+)
12 Laser Modulation (–)
13 Laser Common (+)
14 NC
(5.4 mm)
.213
(LABEL NOT SHOWN)
AND DATE CODE
INCLUDING SERIAL NUMBER
LOCATION FOR LABEL
(1.2 mm)
.049
(12.7 mm)
.500
(parenthesis) MILLIMETERS
DIMENSIONS ARE IN INCHES
(30.0 mm)
1.180
(26.0 mm)
1.025
(20.8 mm)
.820
(8.9 mm)
.350
(2.0 mm)
.078
(2.7 mm)
4X Ø .105
(6.4 mm)
.250
PIN 1
6 SPCS @.100 (2.5 mm)
.400 (10.2 mm) MINIMUM LENGTH
.030 (.8 mm) WIDE X .008 (.2 mm) THICK
LEADS
(6.3 mm)
.248
(1.0 mm)
.040
(5.5 ± .25 mm)
.215 ± .010
(9.3 mm)
.365
(18 ± .8 mm)
.70 ± .03
(5 ± .8 mm)
.19 ± .03
