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Engineering, Technology & Applied Science Research Vol. 11, No. 4, 2021, 7370-7374 7370 
 

www.etasr.com Chughtai: A Realization of Stabilizing the Output Light Power from a Laser Diode 

 

A Realization of Stabilizing the Output Light Power 

from a Laser Diode 
A Practical Approach 

Muhammad Tajammal Chughtai 

Department of Electrical Engineering  

University of Hail 

Hail, Saudi Arabia 
mt.chughtai@uoh.edu.sa 

 

 

Abstract-Semiconductor Laser Diodes (LDs) are known for their 

sensitivity to variation in ambient temperature. With the rise in 

case temperature the threshold current of the LD increases, 

causing the output light power to deteriorate drastically. 

Therefore, it is necessary to stabilize the temperature of the 

diode. Various approaches could be adopted in this regard. In 

this paper, an active cooling approach using the temperature 

compensation technique has been followed and presented in the 

form of a full design of the circuit according to the various 
datasheet parameters of the LD and other components. As a 

result of temperature stabilization, a significant improvement in 

the output light power stabilization was observed and the results 
are presented. 

Keywords-electronics; laser power; temperature stability 

I. INTRODUCTION 

Laser Diodes (LDs) have been known for their sensitivity 
towards changes in the case temperature due to operation over 
long durations or to ambient temperature. With the change in 
temperature, their operating point keeps shifting, i.e. with the 
increase in the temperature it keeps shifting away from the 
original operating point which results in reduced levels of 
optical power output. A proposed remedy to these problems is 
a temperature compensating bias system, which is capable of 
keeping track of any changes in the ambient temperature and 
hence providing a higher safety to the LD. Many approaches 
have been adopted for keeping the operation of LDs stable to 
work in continuous wave mode. One traditional method of 
achieving the objective is attaching a heat sink to the LD. 

Authors in [1] designed a stabilized pump laser system to 
achieve square wave modulation. They managed to attain a 
spot size radius of 7mm, hence obtaining a uniform laser beam 
cove. Authors in [2] proposed an optical scanning system 
wherein they suggested changing the intensity distribution from 
the center and the edge of the beam using a prism. Authors in 
[3] used a double Fabry Perot interferometer acoustic sensor to 
get rid of temperature drifting. Authors in [4] tried a number of 
alterations using silicone converters which helped increase the 
top-limit excitation power ranging from 60 to 180Wcm. 
Authors in [5] developed a heat sink having micro channels, for 
sinusoidal type channel structures which increased the stability 
and life time of the LD. Authors in [6] reported a diamagnetic 

spring to act as a radiation pressure meter. Authors in [7] 
developed a model using Pspice simulation software and a 
comparison between the model and the actual diode was 
studied. The same problem of temperature dependence and 
stabilization in case of high power laser was encountered and 
studied in [8] in the case of high power diode-pumped Tm: 
YLF. The authors achieved optical-to-optical efficiency of 
36.8%. Authors in [9] reported a self-referenced stabilization of 
a diode laser. However, the work was related to a high power 
laser of 2.1W. Similarly, authors in [10] reported the 
stabilization of optical power in high power laser which 
achieved lateral mode stability. This property has been used in 
improving the stability of beam quality. Authors in [11] 
worked towards power stability of a LD output power by 
controlling low and high frequency noises. However the 
stability remained short-term. Authors in [12] achieved 
enhanced stability using double Q switching hence attaining 
mode locked output. The LD under test had a peak power up to 
20W with a good repetition rate. Authors in [13] reported an 
electronic circuit based upon the principle of feedback. The 
circuit was implemented using CMOS technology and gave 
promising results for average output power of hetero-structure 
laser for stabilized continuous operation. 

In order to keep the output optical power constant for a 
constant level of input current it is necessary that the bias 
voltage fed to the LD must track any changes in the 
temperature. Authors in [14] studied the structure of an LD in 
order to compare the LD and a conventional light emitting 
diode. Authors in [15] discussed a technique using Labview 
software to compensate the non-linearity in temperature 
measurement using traditional sensors. A comparison between 
various modes of laser operation has also been presented. 
Authors in [16] presented a review and discussed LD chaos and 
suggested various methods and their advantages for harnessing 
and application of chaos in various applications. Changes in the 
temperature of the LD may cause the operating point voltage of 
the LD to exceed the typical rating value and may cause 
permanent damage or may give a lower than desired amplitude 
of optical power. If the applied voltage exceeds the operating 
voltage (as a result of a decrease in the temperature), a 
permanent damage to the LD may occur. Additionally, a rise in 
temperature will shift the operating point, leading to a drop in 

Corresponding author: Muhammad Tajammal Chughtai



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www.etasr.com Chughtai: A Realization of Stabilizing the Output Light Power from a Laser Diode 

 

optical power output. Authors in [17] studied a semiconductor 
laser using simulations to determine various parameters in 
relation to laser structure hence observing maintenance of 
output parameters at certain structural measurements. Authors 
in [18] discussed a CO2 stabilized laser in cutting processes and 
they carried out a discussion validated by the Analysis Of 
Variance (ANOVA). However, nothing was discussed for the 
stabilization of power. In previous works the temperature 
compensation in a range of applications have been presented by 
using passive [19] as well as active methods which are mostly 
based upon Peltier coolers [20]. The present work has been 
carried out by making use of temperature sensor and reference. 
Therefore, this work is considered as an active method but 
without the use of a Peltier cooler. The complete design and 
calculations are presented with the aim that the users would be 
at ease to carry out calculations on the same pattern. However, 
the researcher has to use parameters, such as the temperature 
coefficient, according to the devices which would be chosen for 
the new system under consideration. 

II. SUGGESTED OPTIONS TO MAINTAIN OPTICAL POWER 
OUTPUT 

The three most common solutions to this problem are: 

• Constant current operation. 

• Maintenance of the temperature of the LD at a constant 
level. 

• Bias the LD using a temperature compensated power 
supply. 

 

 
Fig. 1.  Block scheme for temperature stabilization. 

The constant current power supply circuit is the one 
suggested in [21]. In this circuit a current stabilizer has been 
used to bias the avalanche photodiode, whereas a capacitor Cs 
was used in charge banking role. However, the same 
arrangement may be used for achieving temperature and hence 
output light power stability. This may require a careful redesign 
of the circuit according to the specifications of the LD under 
consideration. Another method of temperature compensation 
can be achieved by ensuring that the voltage of the LD tracks 
any temperature change by using another diode to produce a 
reference voltage signal. The schematic arrangement for such a 
circuit though for photodiode has been presented in [22]. In this 

scheme, a Zener diode was used as a reference diode mounted 
on the same heat sink. The configuration of a differential 
amplifier has been used in the circuit for the purpose of bias 
control. The second method mentioned above, may cause 
condensation on the LD window and hence a poorer delivery of 
optical power output and the need to clean the window 
frequently. The third method to stabilize an LD is to design a 
circuit using temperature sensing components, as shown in 
Figure 1. Usually, temperature sensing components produce a 
current signal which varies with any change in temperature. 
This output current may be converted to voltage with the use of 
an operational amplifier, configured as a current to voltage 
converter. The output of this op-amp can then be fed to a 
summing amplifier in a non-inverting configuration, thereby 
summing up the voltage with the negative value from a 
conventional high voltage power supply and a reference 
voltage. The resultant output is used to control the base current 
of the bias control transistor. 

III. DESIGN CONSIDERATIONS 

A Toshiba LD was used in this study. The temperature 
coefficient for this particular LD as given by the data sheet is 
1×10

-3
%/°C. In order to convert this temperature coefficient 

into a voltage variation (Volts/°C), noting that: 

3
1 10

100
β

−
×

=     (1) 

where β is the temperature coefficient of the LD in volts/°C 
and VB is the bias voltage of the LD. The value of VB for this 
case is 3V, so (1) leads to [23]: 

O

30µV
C

β =     (2) 

The practical circuit for a temperature compensated bias 
supply for an LD is illustrated in Figure 2. 

 

 
Fig. 2.  Schematic of the temperature compensated bias supply for LD. 

In order to understand the functioning of this, a gradual 
design and analysis of the circuit is presented below. 

A. Constant Reference Voltage 

A constant voltage reference of −6.8V was obtained using 
the precision reference diode package LM329. This constant 



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reference voltage was then supplied to the temperature sensor 

1C AD590, which has a temperature coefficient of 1µA/°K. 

B. Current to Voltage Converter 

Let us consider the combination of the temperature sensor 
IC1 and the operational amplifier A1. The total current 
generated by 1C1 for a rise of T (

o
K) in the temperature will be 

T×10
-6
A. Hence, the current I supplied by the temperature 

sensor for a rise of T 
o
K will be: 

6

O
10 A

K
I T

−

= ×     (3) 

Therefore, the voltage at the output of the op-amp A1 with 
feedback resister R1 can be expressed as: 

6 1

1

10
V

T
R

−
× =  

Thus, the voltage change Vl, becomes: 

6

1 1
10 VV R T

−
= × ×     (4) 

C. The Summing Amplifier 

The operational amplifier A2 was used in a summing 
amplifier configuration so that it added all three voltages 
applied at its inputs to produce the output Vo. This output Vo 
was supplied at the base of an NPN transistor Q1, through a 
resistor. Transistor Q1 was configured so that the smaller the 
voltage signal at its base, the lower was the conduction 
between the collector and the emitter. When conducting, the 
transistor produced a flow of current between its collector and 
emitter of Q1. In turn, this caused the +bias voltage point to 
float, hence, a variation in the -bias voltage point at the output 
could be observed. Mathematically, this section of the circuitry 
can be expressed as follows: 

Kirchhoff's current law states that, at any point in an 
electrical circuit, the algebraic sum of the currents meeting at 
that point is zero (Figure 3). Therefore, the current equation 
according to Kirchhoff’s law at the input of A2 can be written 
as: 

1

2 4 3

0
ref B

V V V

R R R
+ + =     (5) 

However, substituting the value of V, from (4), (5) yields: 

6

1

2 4 3

10
0

ref B
V V T R

R R R

−
× ×

+ + =     (6) 

Differentiating (6), with respect to T, yields: 

6

1 4

3

10
B

dV R R

dT R

−
× ×

= −     (7) 

Putting up dVb/dT = β, (7) can then be written as: 

6

1 4

3

10R R

R
β

−
× ×

= −     (8) 

This gives the value for the temperature coefficient β of the 
LD. Substituting this value into (5) gives: 

4

2

ref

B

V R
V T

R
β

×
= − + ×     (9) 

Solving (5), (8), and (9) simultaneously, the values for 
resistors R2, R3 and R4 may be calculated. 

IV. PRACTICAL IMPLEMENTATION 

From the data provided with the LD, the bias voltage of the 
particular LD under consideration was found to be 3V and, 
according to this value, the temperature coefficient as 
calculated at the beginning was 30µV/ºK. In order to calculate 
the appropriate values of the various resistors to be used in the 
circuit, this voltage value must be substituted into (2) using 
R1=20KΩ. This produces: 

6

6 4

3

20 10
30 10

k R

R

−

− × ×
− × =  

Thus: 

34

3

1 5
1 5 10

1

R .
.

R k

−
= = ×     (10) 

Leading to the value 666×R4=R3. Since it was already 
required that the LD should operate at a temperature of 300ºK 
(i.e. approximating to a normal room temperature, this implied 
that the following values were already fixed): 

T = 300ºK 

β = −300µV/ºK 

R1 = 20kΩ 

Inserting these values in (9) led to a value for the reversed 
breakdown voltage: 

4

2

0 09
B ref

R
V V .

R
= − −  

Furthermore, it was required to operate the LD at a biasing 
voltage value VB = 3 Volts. Therefore: 

4

2

3 0 09
ref

R
. V

R
+ = −  

but: 

Vref=5V 

4

2

0 618
R

.
R

=  

Assuming that R2=10kΩ, (10) therefore leads to: 

R4=10k(0.618)=6.18k ≈ 6kΩ 
and: 



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www.etasr.com Chughtai: A Realization of Stabilizing the Output Light Power from a Laser Diode 

 

2 3

6 18
4 1MΩ

1 5 10

. k
R .

.
−

= =
×

 

Inserting these design values for R1, R2, R3, and R4 into the 
circuit design, satisfactory performance of the temperature 
compensated power supply for the LD was obtained. However, 
in order to set the value of the temperature coefficient 
precisely, it was decided to insert a variable resistor instead of a 
fixed value for R2. This could then be adjusted until the 
required output value of the bias voltage was obtained. The 
designed circuit was assembled on a double sided Printed 
Circuit Board (PCB) and is shown in Figure 3. 

 

 
Fig. 3.  Assembled circuit as used for testing and confirmation. 

V. RESULTS AND DISCUSSION 

The performance of the LD was recorded with and without 
applying the temperature compensated bias circuit. Figure 4 
shows the trend of the LD output power. 

 

 
Fig. 4.  LD output power without temperature stabilization. 

The graph shows a drastic reduction in output optical power 
during the first 50 minutes of switching on. After 50 minutes of 

biasing up the LD lost more than 50% of its rated value before 
the output optical power settled down but the level of output 
power was at such a low level, which is not good enough for 
the purposed application. Figure 5 shows a power drop of over 
1mW before it settles down around 10mW of optical power, 
which was a sufficient and constant supply of optical power for 
the system under consideration. The circuit for temperature 
compensation of the LD was implemented and assembled on a 
double sided PCB, according to the design values of the 
components calculated in the previous section. In order to 
measure the variation in the optical power output, the 
observations were recorded for power output against time, as 
shown in Figure 6. These were then plotted in the form of a 
graph for comparison purposes. The output power level was 
also recorded without temperature compensation, so that an 
easy comparison of both the situations could be made. It can be 
observed that the output optical power is well stabilized after 
attaching the LD to temperature compensation arrangement. 

 

 
Fig. 5.  Stabilized output optical power after applying modified bias 

circuit. 

 
Fig. 6.  Comparative graph of stabilized and un-stabilized output optical 

power. 

VI. CONCLUSIONS 

Reliable and reproducible results have been achieved using 
the designed parameters. The circuit was first tested as a 
prototype and then assembled on a double sided PCB. A 
complete set of design calculations along with the choice of 
components and any assumptions made has been presented. 
The utilization of the designed circuit may be extended to other 
temperature sensitive applications.  

ACKNOWLEDGEMENT 

The author is thankful to the University of Hail, Hail, Saudi 
Arabia for providing the grant (RG20-013) to carry out this 
work. 



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