Indonesian Review of Physics (IRiP) Vol. 3, No 2, December 2020, pp. 35-39  
 DOI: 10.12928/irip.v3i2.2074 

 

http://journal2.uad.ac.id/index.php/irip 
35 

 

The Effect of the Installation Angle of the Sky Quality Meter on the Night Sky 
Brightness and the Beginning of the Fajr Prayer Time   

Abu Yazid Raisal*, Muhammad Hidayat, Leo Hermawan and Arwin Juli Rakhmadi  
Observatorium Ilmu Falak, Universitas Muhammadiyah Sumatera Utara  
Jl. Denai No.217, Kec. Medan Denai, Medan, Sumatera Utara, Indonesia  
*Email: abuyazidraisal@gmail.com  
 

Article Info ABSTRACT 

Article History 
Received Apr 18, 2020 
Accepted Nov 26, 2020 
Published Dec 31, 2020 

Measuring the brightness of the night sky and determining the start of Fajr prayer 
times can be done using SQM. Observations were made at OIF UMSU with 
coordinates 3o 34' 55.06" N and 98o 43' 17.09" E. The sky brightness was measured 
using three SQMs mounted facing the zenith, eastern horizon, and western horizon. 
The night sky brightness values for SQM directed to the zenith, eastern horizon, and 
western horizon are 18.23 mpsas, 15.82 mpsas, and 15.47 mpsas. The beginning of 
fajr prayer time produced by SQM is after the beginning of fajr prayer time obtained 
using the Accurate Times concerning the Sun's altitude 18o below the horizon. The 
difference obtained by SQM directed to the zenith, eastern horizon, and western 
horizon is 29.5 minutes, 36.7 minutes, and 39.5 minutes. In other words, the 
beginning of Fajr prayer time used in Indonesia is earlier than it should be. 

Keywords: 
Fajr prayer time 
Light pollution  
Night sky brightness 
Sky Quality Meter 
 

To cite this article: 
A. Y. Raisal, M. Hidayat, L. Hermawan, and A. J. Rakhmadi, “The Effect of the Installation Angle of the Sky Quality 
Meter on the Night Sky Brightness and the Beginning of the Fajr Prayer Time,” Indones. Rev. Phys., vol. 3, no. 2, pp. 
35–39, 2020. 

 

 
I. Introduction  

Observing the stars during the night is an exciting 
task to be done. That can only happen if the sky is free of 
light pollution. Globally, light emission has become a 
concern because it progressively decreases the possibility 
of seeing stars and reduces the number of light-sensitive 
species [1], [2]. However, the public often ignores these 
problems even though the adverse effects of light 
pollution are known. In contrast to other pollution, light 
pollution does not mean light that gets the impact of 
pollution, but light itself is a pollutant for the night sky's 
dark conditions [3]. 

The larger the human population, the more light is 
needed to illuminate human activities at night. Light 
pollution is a condition where, due to accidental 
illumination caused by improper lighting design, species 
are exposed to light at the wrong location, time, and 
intensity [4]. Light pollution has a significant effect on 
the night sky brightness. Therefore, it is necessary to 
measure the night sky brightness to determine the 
pollution level and become a reference for making 
policies in outdoor lighting systems [5]. The night sky 
brightness can be measured using the Sky Quality Meter 
(SQM). SQM is a system used for calculating night sky 
illumination. With a size that is easy to hold, this tool 
makes it possible for the general public to measure the 
night sky's quality whenever and wherever [6]. Besides, 
this tool is also the choice of night sky brightness 
researchers because it is user friendly and has good after-
sales service and support [7]. SQM is also used to assess 

the eclipse period and the beginning of the Fajr prayer 
time [8], [9].  

SQM has a field of view around 20o with an 
uncertainty of the order of 10% [10]. With an area of 
view of 20o, SQM does not record the sky as a whole. In 
general, the Sun rises from the eastern horizon. The 
eastern horizon is bright earlier than the zenith and the 
western horizon. This study entitled the analysis of the 
influence of the Sky Quality Meter's angle on the night 
sky's brightness and the beginning of the Fajr prayer time. 
This study aims to determine whether there are 
differences in the value of the night sky brightness in the 
sky toward the east horizon, zenith, and west horizon. 
Besides, this study also aims to look for the effect of 
different SQM angles on the beginning of Fajr prayer 
time. 

 

II. Theory 
SQM is divided into two types, namely SQM 

without a lens and SQM using a lens. SQM that uses a 
lens (L) has a smaller view than without a lens around 
20o, as shown in Figure 1. With a smaller field of view, 
the data reading will be more consistent when the nearest 
light source appears [11]. SQM measures the night sky 
brightness in magnitude per square arcsec or 
mathematically written mag/arcsec2 (mpsas).  



A. Y. Raisal, et al. / Indonesian Review of Physics 3 (2), 2020, 35-39 36 
 

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e-ISSN: 2621-2889 

 

 
 

Figure 1. Different types of SQM  
(https://www.unihedron.com) 

 
SQM is usually used to find out light pollution in an 

area. Light pollution is caused by the improper and 
excessive use of artificial light. Light pollution is a 
significant problem throughout the world, especially in 
urban areas. It causes an increase in the sky's light and 
prevents us from observing the dark starry sky [12]. 
Besides being used to measure the level of light pollution, 
SQM is also used to determine the beginning of the Fajr 
prayer time. 

The beginning of Fajr prayer time is defined at the 
dawn of sadiq seen on the eastern horizon. The dawn 
sadiq is a white light visible on the east horizon and 
spread horizontally that appears before sunrise [9]. Dawn 
sadiq in astronomy is understood to be the astronomical 
dawn when the Sun is 18o below the horizon, as seen in 
Figure 2. However, there are differences in the Sun's 
altitude in some countries, as shown in Table 1. 

 

 
 

Figure 2. Overview of dusk and dawn 
(https://www.weather.gov) 

 
When the SQM value decreases gradually, it is 

defined as the emergence of the dawn of Sadiq. To 
determine when the SQM value decreases gradually, one 
can use several methods, one of which is the moving 
average method [13]. 

Table 1. The Sun's altitude in determining the dawn Sadiq in 
several countries [14] 

No Convention 
Sun's 

altitude 
1 Shiah Ithna Ashari (Jaafari) -16o 
2 Islamic Society of North America (ISNA) -15o 
3 Muslim World League (MWL) -18o 
4 Umm Al-qura Makkah -18.5o 
5 Egyptian General Authority of Survey -19.5o 
6 University of Islamic Science, Karachi  -18o 
7 Malaysia -20o 

 

III. Method 
Observations were made at the Falak Observatory of 

the University of Muhammadiyah North Sumatra (OIF 
UMSU) with coordinates 3o34'55.06" N and 98o43'17.09" 
E. OIF UMSU is located on the 7th floor of UMSU 
Postgraduate School, with a height of about 35 meters. 
The sky brightness was measured using three SQM 
mounted facing the east horizon, zenith, and west 
horizon. SQM, which measures the west horizon's 
direction, uses SQM-LU and SQM, which measures the 
zenith's direction and the east horizon uses SQM-LU-DL. 
SQM is set to collect the sky brightness value every 2 
seconds. Measurements are taken throughout the night 
from sunset to sunrise. SQM data used is during the new 
moon phase. Hence, the moonlight does not affect the 
night sky brightness. The Moon Phase is one of the 
variables affecting the visibility of the night sky [15]. 
Besides, solar activity also affects the night sky 
brightness [16]. 

Determination of the beginning of Fajr prayer time 
using the moving average method. The moving average 
method is a method that is often used in technical 
analysis that shows the average value during a specified 
period. SQM retrieves data every 2 seconds then each 
difference value is sought by subtracting the second data 
from the first data. Furthermore, the difference in data is 
processed with a moving average. The interval used is 30 
data. It was taken because of the need for prayer time 
with a resolution of 1 minute. Then the Fajr prayer time 
obtained by SQM is compared to the prayer time obtained 
by Accurate Times. This application can indicate the start 
of dawn based on the desired Sun's altitude. In this study, 
the Sun's altitude was chosen to be 18o below the horizon 
as a comparison. 

 

IV. Results and Discussion 
Three SQMs are placed respectively towards the 

zenith, the western horizon, and the eastern horizon, as 
seen in Figure 3. Each SQM is inserted into the holding 
so that it can retrieve data even when it is raining. Data is 
collected from August 2018 to June 2019. During the 
new moon phase, the time taken is so that the moonlight 
does not affect the night sky brightness value. 
Furthermore, SQM directed to the zenith will be written 
as SQM1, SQM referred to the eastern horizon is written 



A. Y. Raisal, et al. / Indonesian Review of Physics 3 (2), 2020, 35-39 37 
 

http://journal2.uad.ac.id/index.php/irip p-ISSN: 2621-3761 
e-ISSN: 2621-2889 

 

as SQM2, and SQM referred to the western horizon is 
written as SQM3. 

  

 
       (a)           (b) 

Figure 3. (a) SQM directed to zenith and east horizon. (b) SQM 
directed to west horizon. 

 
SQM output data consists of universal time, local 

time, time, voltage temperature, sky brightness value, and 
data units. Furthermore, local time and sky brightness 
values will be used. The SQM data used is limited from 
midnight until SQM shows zero value. It is done to 
reduce the influence of light used by the community 
around the observation site. 

Figure 4 is a graph of the night sky brightness 
against local time on June 5, 2019. The night sky 
brightness values of SQM1, SQM2, and SQM3 are 
shown by red, blue, and green lines. The night sky 
brightness value is relatively constant at night; then, it 
will decrease when the Sun rises. Figure 4 shows that the 
sky brightness value of SQM1 has a higher value than 
SQM2 and SQM3. 

 

  
 

Figure 4. Night sky brightness against local time on June 5, 
2019 

During data collection, the effects of light, cloud, 
and air pollution are inevitable. It affects the value of the 
night sky brightness, which is read by SQM. Therefore 
the darkest value that can be obtained by SQM is taken 
during data collection. Table 2 shows the maximum night 
sky brightness values obtained by the three SQMs from 
August 2018 to June 2019. The maximum sky brightness 
value from SQM obtained varies. The maximum night 
sky brightness values obtained by SQM 1, SQM2, and 
SQM3 range from 17.43-18.89 mpsas, 15.57-16.01 
mpsas, 15.02-15.71 mpsas. The average the night sky 
brightness value for SQM1, SQM2, and SQM3 are 18.23 
± 0.49 mpsas, 15.82 ± 0.15 mpsas, and 15.47 ± 0.23 
mpsas, respectively. 

Table 2. The maximum night sky brightness values 

Date 
SQM1 

(mpsas) 
SQM2 

(mpsas) 
SQM3 

(mpsas) 
13/8/18 18.71 15.76 15.68 
11/9/18 18.89 15.73 15.60 
11/10/18 17.59 15.57 15.39 
9/11/18 17.43 15.59 15.11 
9/12/18 18.00 15.81 15.68 
8/1/19 18.57 15.98 15.71 
7/2/19 18.37 15.90 15.61 
8/3/19 18.39 15.95 15.51 
11/4/19 18.22 15.93 15.42 
6/5/19 18.67 16.01 15.42 
5/6/19 17.71 15.82 15.02 

Average 18.23 15.82 15.47 

 
The night sky brightness at the observation location 

based on the light pollution map info has a 19.02 mpsas, 
as shown in Figure 5. Compared with the maximum night 
sky brightness value obtained from SQM1, SQM2, and 
SQM3, there is a difference of 0.79 mpsas, 3.2 mpsas, 
and 3.55 mpsas. 

 

 
 

Figure 5. Night sky brightness values at the observation 
location (https://www.lightpollutionmap.info) 

SQM LU and SQM LU-DL use lenses and have a 
field of view of 20o. Hence, the SQM directed to the west 
horizon and east horizon at a certain distance will 
immediately read the effect of the light produced by 
trespass light around the observation location. In the west 
of the observation site, several hotels are higher than the 
observation location. The value obtained by SQM 
directed to the western horizon has the lowest sky 
brightness value than the others. 

Figure 6 shows a graph of the night sky brightness 
before sunrise on June 5, 2019. At the time before 
sunrise, the value of the brightness of the sky will 
decrease gradually. It is because the Sun's rays start to 
illuminate the Earth's atmosphere even though the Sun is 
still under the horizon. From Figure 6, it can be seen that 
SQM1 has gradually decreased faster than the other two. 
When the sky's brightness decreases gradually, this is 
considered the beginning of the fajr prayer. Nevertheless, 
it is complicated to determine when the sky's brightness 
value drops gradually by looking at Figure 6. 
 



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e-ISSN: 2621-2889 

 

 

Figure 6. The brightness of the sky before sunrise on June 5, 
2019. 

 
Figure 7 shows a graph of the moving average value 

against SQM1 time on June 5, 2019. The sky brightness 
values obtained are not always the same. The moving 
average value indicates positive, zero, and negative 
values. This condition occurs due to light, cloud, and air 
pollution. The moving average value gradually decreases, 
or the negative value obtained is getting bigger at a 
specific time. It is due to the sky brightness value, which 
drops gradually. The time at which the moving average 
shows zero before the data afterward indicates a negative 
value is determined as the beginning of the Fajr prayer 
time. 

 

 

Figure 7. Graph of the moving average value against the local 
time in SQM1 on June 5, 2019 

 
Table 3 shows the beginning of the Fajr prayer time 

based on SQM and Accurate Times. The beginning of 
Fajr prayer time at the Sun's altitude 18o below the 
horizon is written as T18. It can be seen that the 
beginning of Fajr prayer time based on SQM is after the 
beginning of Fajr prayer time using Accurate Times. 

Table 4 shows the differences between the 
beginning of Fajr prayer time of SQM and T18. The 
difference obtained varies from 19 minutes to 48 minutes. 
SQM1 has a smaller difference than SQM2 and SQM3. 
The average difference between the initial dawn time 
obtained by SQM1, SQM2, and SQM3 were (29.5 ± 8.9) 
minutes, (36.7 ± 6.3) minutes, and (39.5 ± 5.4) minutes, 
respectively. There are several high-rise buildings in the 
west of the observation site, while in the east, there are 
residential areas, so light pollution in the west and east is 

higher than the zenith direction. Besides, the sky on the 
eastern and western horizon is often covered with clouds. 
Therefore, the change in the sky brightness value is after 
the zenith. 

 

Table 3. The beginning of Fajr prayer times based on SQM and 
Accurate Times 

Date SQM1 SQM2 SQM3 T18 
13/8/18 05.30 05.38 05.42 05.11 
11/9/18 05.47 05.53 05.51 05.08 
11/10/18 05.46 05.49 05.48 05.01 
9/11/18 05.38 05.36 05.40 04.58 
9/12/18 05.32 05.43 05.42 05.05 
8/1/19 05.42 05.53 05.53 05.19 
7/2/19 05.48 05.57 06.03 05.28 
8/3/19 05.48 05.57 06.03 05.25 
11/4/19 05.35 05.45 05.47 05.11 
6/5/19 05.36 05.41 05.49 05.02 
5/6/19 05.30 05.39 05.43 04.59 

 
Table 4. The differences between the beginning of Fajr prayer 

time of SQM and T18. 

Date 
SQM1 

(minutes) 
SQM2 

(minutes) 
SQM3 

(minutes) 
13/8/18 19 27 31 
11/9/18 39 45  43 
11/10/18 45 48 47 
9/11/18 40  38  42  
9/12/18 27  38  37  
8/1/19 23  34  34  
7/2/19 20  29 35  
8/3/19 23  32  38  
11/4/19 24  34  36  
6/5/19 34  39  47  
5/6/19 31  40  44  
Average 29.5 36.7 39.5 

 
From Table 4, it can be concluded that the 

beginning of Fajr prayer time obtained by SQM is longer 
than T18. When compared with the beginning of Fajr 
prayer time concerning the height of the Sun 20o below 
the horizon, the difference obtained will be more 
significant than that shown in Table 4. At the same time, 
the beginning of Fajr prayer time, often used in 
Indonesia, uses a reference of 20o. It indicates that the 
Fajr prayer time used in Indonesia is earlier than it should 
be.  

 

V. Conclusion 
The night sky brightness values for SQM1, SQM2, 

and SQM3 are (18.23 ± 0.49) mpsas, (15.47 ± 0.23) 
mpsas, and (15.82 ± 0.15) mpsas, respectively. With a 
field of view of 20°, SQM directed to the west horizon, 
and the eastern horizon at a certain distance will 
immediately read the effect of light produced by trespass 
light around the observation site. So the night sky 
brightness value obtained by SQM2 and SMQ3 is smaller 
than SQM1. The night sky brightness value of SQM3 is 
the lowest compared to the others. Due to the west of the 



A. Y. Raisal, et al. / Indonesian Review of Physics 3 (2), 2020, 35-39 39 
 

http://journal2.uad.ac.id/index.php/irip p-ISSN: 2621-3761 
e-ISSN: 2621-2889 

 

observation site, several hotels are higher than the 
observation location.  

The beginning of dawn produced by SQM is after 
the beginning of dawn obtained using the Accurate Times 
with a height of 18° below the horizon. The difference 
obtained by SQM directed to the zenith, eastern horizon, 
and western horizon is 29.5 minutes, 36.7 minutes, and 
39.5 minutes. In other words, the beginning of Fajr prayer 
time used in Indonesia is earlier than it should be. 

 
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