The results of atmospheric parameters measurements in the millimeter wavelength range on the radio astronomy observatory “Suffa Plateau”


ACTA IMEKO 
ISSN: 2221-870X 
June 2023, Volume 12, Number 2, 1 - 5 

 

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The results of atmospheric parameters measurements in the 
millimeter wavelength range on the radio astronomy 
observatory “Suffa Plateau” 

Dilshod Raupov1,2, S. Ilyasov1,2, G. I. Shanin3 

1 Ulugh Beg Astronomical Institute, Uzbek Academy of Sciences, Tashkent, Uzbekistan  
2 Jizzah State Pedagogical University, Jizzah, Usbekistan  
3 Radio observatory RT-70, Uzbek Academy of Sciences, Tashkent, Uzbekistan  

 

 

Section: RESEARCH PAPER  

Keywords: astroclimate; turbulence; transparency windows; atmospheric absorption; precipitated water; radio range; millimeter wave; Neper 

Citation: Dilshod Raupov, S. Ilyasov, G. I. Shanin, The results of atmospheric parameters measurements in the millimeter wavelength range on the radio 
astronomy observatory “Suffa Plateau”, Acta IMEKO, vol. 12, no. 2, article 18, June 2023, identifier: IMEKO-ACTA-12 (2023)-02-18 

Section Editor: Francesco Lamonaca, University of Calabria, Italy 

Received December 12, 2022; In final form January 30, 2023; Published June 2023 

Copyright: This is an open-access article distributed under the terms of the Creative Commons Attribution 3.0 License, which permits unrestricted use, 
distribution, and reproduction in any medium, provided the original author and source are credited. 

Corresponding author: Dilshod Raupov, e-mail: dilshod@astrin.uz   

 

1. INTRODUCTION 

Recently, thanks to the rapid development of microwave 
technology, the creation of adaptive large-aperture radio 
telescopes and the possibility of combining them into a system 
of ground-based and ground-space interferometers with very 
long bases, has gained considerable interest In fact, this 
represents a real possibility to fully realize the advantage of the 
millimetre range in solving fundamental problems of cosmology, 
as well as in solving a number of applied problems at a 
completely new level. 

At the same time, such a rapid technological breakthrough in 
the development of microwave technology inevitably required 
the solution of new problems in a detailed study of the 
parameters of the medium for the propagation of mm-wave 
radio waves. 

Significant factors, in addition to insignificant attenuation in 
space plasma due to scattering and absorption, affecting the 
propagation of mm waves from the source of radiation to 

terrestrial observation are distortions introduced by the terrestrial 
atmosphere. 

In addition, the Earth's atmosphere absorbs electromagnetic 
radiation of most wavelengths. However, there are frequency 
bands (radio windows) in which the atmosphere is substantially 
transparent. Such a radio window in the mm region of the 
spectrum is a region from 1 to 15 mm, in which several 
absorption lines of oxygen and water vapor are located. 

A large number of papers and monographs have been 
devoted to theoretical studies of molecular absorption of mm 
waves. In these papers, it is emphasized that, in theoretical 
absorption calculations, special attention should be paid to the 
feasibility of the physical approximations used and to the 
adequacy of the description of the corresponding processes. 
From this point of view, interesting results were obtained in [1], 
where it was possible to achieve agreement between the theory 
of molecular absorption in water vapor in transparency windows 
and experimental data by taking into account the duration of 
molecular collisions in the framework of the memory function 
method. 

ABSTRACT 
The results of measurements of atmospheric absorption and the amount of precipitated water on the Suffa Plateau for the period from 
January, 2015 to November, 2020, are presented. The measurements of atmospheric parameters in the 2 and 3 mm range of the radio 
waves spectrum were carried out using the MIAP-2 radiometer. The results of more than six years of measurements have show that on 
the Suffa Plateau, atmospheric parameters in the above range remain fairly stable. The median value of the atmospheric absorption and 
the amount of precipitated water over the entire observation period were 0.14 and 0.12 Nep and 5.91 and 9.83 mm, respectively, for 
the ranges of 2 and 3 mm. 

mailto:dilshod@astrin.uz


 

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Noteworthy are the calculations of absorption in water vapor 
and in molecular oxygen [2], [3] using natural (from a balloon) 
and laboratory measurements [4], taking into account the 
influence of the Earth's magnetic field on the characteristics of 
the propagation of millimeter waves in the region λ = 5 mm. 
However, in theoretical calculations, there is still a problem of 
correct comparison of the theory of molecular absorption of 
millimeter waves with experimental and laboratory data, as well 
as with insufficiently studied statistical characteristics of 
fluctuations of atmospheric meteorological parameters. 

Recently, interest has been growing in the construction of 
radio models of the atmosphere, with the help of which it would 
be possible to determine quickly (and with fair reliability) the 
characteristics of the propagation of millimeter waves along 
paths of various orientations and lengths. 

In the radio model constructed in [5], the input parameters 
are meteorological elements (pressure, temperature, humidity), 
the concentration of water particles suspended in the air, and the 
intensity of rain. The model makes it possible to calculate the 
influence of the attenuating and refractive characteristics of the 
medium on the propagation of radio waves in various 
atmospheric conditions. However, the authors note the need to 
refine and supplement the model and, first of all, the need for a 
much more thorough meteorological support. 

Recently, scientists have paid much attention to the study of 
the influence of atmospheric parameters on the characteristics of 
microwave radio waves both in areas that are promising for the 
installation of large radiometric systems, and at operating 
complexes. One of such radiometric complexes being created on 
the Plato de Chajnantor in the Central Andes (Chile) is ALMA 
(Atacama Large Millimeter Array) [6], [7]. Another potential site 
for installing mm-submm telescopes is Antarctica (South Pole), 
where the Dome-C Antarctic observatory is being created on a 
plateau at the altitude of 2835 m [8]-[10]. Detailed studies of 
transparency and stability of atmosphere in this range were also 
carried out at Mauna Kea (Hawaiian Islands, USA) [11], where 
submillimeter telescopes (in particular, the SMA complex - 
submillimeter array) are installed. Radio transparency studies for 
mm-submm astronomy were also carried out at the Indian 
Astronomical Observatory Hanle in the Himalayas in 2000-2003. 
[12], Pampa la Bola (8 km NE from Chajnantor) [13], Rio Frio 
[14].  

Water in different phases and mixtures is a key element of 
the climate system. Long-term chemical and isotopic changes of 

oceanic and atmospheric water mixtures must be monitored 
regularly and precisely [15]. 

The study of the atmospheric absorption at the Radio 
Astronomy Observatory "Suffa Plateau" (Uzbekistan) has been 
carried out from 2015 to 2020 in atmospheric transparency 
windows of 2 and 3 mm using the MIAP-2 measuring complex. 
A detailed description of the radiometer, its functional diagram, 
basic principles of measurements and calculations, estimates of 
permissible errors are given in [16].  

2. CHARACTERISTICS OF THE MEASURING COMPLEX 

The MIAP-2 measuring complex is a radiometric system that 
includes two radiometers for frequencies of 84-99 GHz 
(λav = 3 mm) and 132-148 GHz (λav = 2 mm), a turntable and a 
control, acquisition and processing system based on a personal 
computer. 

The receiver in the range (84-99) GHz is made according to 
the direct amplification scheme with detection at the 
fundamental frequency. The modulator at the input of the 
receiver is made on the basis of chains of series-parallel 
connected diodes with a Schottky barrier (SBB) installed in the 
waveguide of the main section. The modulator control and 
synchronous data acquisition are carried out using a PC via the 
USB-4716 module. The modulation frequency is about 36 Hz. 
The noise temperature of the receiver is 1300 K.  
The solid-state receiver of the radiometer in the range (132-
148) GHz is made according to the super heterodyne circuit and 
includes a local oscillator based on the Gunn diode, a balanced 
mixer on the DBSH and an IF in the range (4-8) GHz. The 
modulator is similar to the one described above, it is also 
controlled and data is collected via the USB-4716 module. The 
modulation frequency is also about 36 Hz. The noise 
temperature of the receiver is 6300 K. 

The turntable consists of a support frame for mounting the 
radiometer module, a swivel mirror, and a mirror drive system 
based on a stepper motor. The weather protection housing is 
made of stainless steel and has a radio-transparent PTFE 
window. The limits of change of the angle of observation are 0º-
90º. The drive is controlled according to a given program via the 
USB-4716 module. 

The control, data collection and processing system ensure 
fully automatic operation of the complex in the mode of cyclic 
observations at a given time. 

Both radiometers are equipped with lens antennas with a 
conical feed. The lenses are made of Teflon and are limited on 
one side by a hyperbolic surface and flat on the other. Each of 
the boundary surfaces has an enlightenment, which is made in 
the form of periodic circular concentric grooves 
("corrugations"), providing a reflection coefficient in the entire 
operating range of each of the radiometers no more than 0.5 %. 
The irradiators are in the form of circular cones with a break. 
The antenna beam width at half power level in both bands is 
about 2.5º. 
Atmospheric absorption measurements of radio waves in the 
millimetres range carried out by the method of vertical cuts were 
described in [17]. The method is based on measuring the intrinsic 
thermal radiation of the atmosphere, while comparing the 
brightness temperature increments of two parts of the 
atmosphere at different zenith angles relative to the known 
temperature of a certain reference region. 
In spite of all its advantages, this method is limited by the choice 
of one or another model of the structure of the atmosphere. In 

 

Figure 1. Location of the Suffa Plateau (λ = 65°26, ϕ = 39°37, h = 2500). 



 

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particular, it is assumed that the Earth's atmosphere is isothermal 
in horizontal coordinates, which can lead to errors associated 
with drifting temperature in homogeneities of the surface layers 
of the atmosphere. 

The measurement principle is illustrated in Figure 2. The left 
side shows a typical temperature distribution in the troposphere 
with respect to height (the so-called temperature profile). In the 
middle - a typical distribution of humidity in height. These 
profiles are subject to significant seasonal and daily changes, in 
fact, from them it is possible to calculate the amount of deposited 
water and extrapolate it to absorption. On the right are the zenith 
angles (that is, the number of atmospheres) by which the 
radiometer approximates the brightness temperature profile. 

Before starting, the device is set to a strictly horizontal 
position according to the hydraulic level. The measurement cycle 
begins with the rotation of the mirror along the photo sensor 
exactly in the "zenith" direction. Next, the mirror is moved using 
a stepper motor (the “step” value is 0.72 degrees) to a certain 
angle, the brightness temperature of the “spot” of the sky in the 
direction of observation is measured, the mirror moves to the 
next angle, the next measurement is made, etc. The signal 
averaging time can be changed from 1 s (with a “calm” 
atmosphere) to tens of seconds. 

The signal through the amplitude-to-digital converter (ADC) 
enters the computer. Next, a system of two (measurement at two 
angles) and five (measurement at five angles) equations is solved. 
The calculated value of atmospheric absorption is displayed on 
the graph. The cycle lasts about a minute, then the mirror is 
brought to its original position, the calculated transparency value 
is entered into the database and marked on the graph, after which 
the device is ready for the next measurement cycle. The time 
interval between cycles also varies widely, depending on the task 
set by the observer. 

With the help of the control program of the complex, it is 
possible to select any observation angles in the range from 
0° (zenith) to 90° (horizon). However, this choice should take 
into account both the sensitivity of the device (it is necessary that 
the "neighbouring" corners have a difference in brightness 
temperatures distinguishable by the device), and some features 
of its design. The point is that the error introduced into the 
measurements and associated with the finite width of the 
radiation pattern and a fairly wide bandwidth has a complex 
dependence on the observation angle. An appropriate selection 
of angles can minimize this error. When processing the results 
from two angles, these angles are 60.5° and 76.3° (corresponding 

to approximately two and four atmospheric thicknesses 
overcome by the signal). When processing five corners, the most 
rational choice is: 60.5°, 76.3°, 81.4°, 84.2°, 88.6°. The last corner 
is as close as possible to the horizon. 

Close absorption values obtained by processing the results of 
measurements at 2 and 5 angles indicate both the normal 
operation of the device and the absence of interference in the 
form of clouds or ground objects (at the “lowest” angle) in the 
direction of observation, as well as “calm state of the 
atmosphere. 

After processing each cycle of measurements, we directly 
obtain the value of atmospheric absorption at the zenith, 
expressed in Neper (1 Nep = 8.686 dB), i.e. the so-called optical 
thickness of the atmosphere. This value is subject to significant 
seasonal and daily changes, which is primarily due to changes in 
the total content of water vapor in the atmosphere. 

At the end of the observation session, we obtain a chronology 
of absorption changes in two bands during the observation time. 
Any observation period can be chosen. The possibility of round-
the-clock monitoring of radio transparency is provided. 

The total absorption of radio waves of the specified range 
includes absorption by oxygen molecules, water vapor contained 
in the atmosphere, and absorption in clouds. In clear time, the 
third component naturally vanishes. Oxygen absorption varies 
little for a particular observation site over time due to its relatively 
constant content in the atmosphere. It is almost constant and 
depends only on the height of the observation site. Thus, the 
change in radio transparency is mainly due to a change in the 
amount of water vapor in the atmosphere, or, in other words, a 
change in the amount of precipitated water. 

3. OBSERVATIONAL STATISTICS 

The significant array of measurements of atmospheric 
absorption in the mm spectral range has been accumulated on 
the Suffa plateau for the period from January 2015 to November 
2020.  

As an example, the full time series of atmospheric absorption 
obtained on the Suffa plateau for the above period are shown in 
the 2 mm radio wave band is shown in Figure 3. Some gaps of 
data in observations is due to technical reasons. As can be seen 
from the figure, the value of atmospheric absorption over the 
entire observation period remains stable. A similar trend is also 
observed in the values of atmospheric absorption and the 
amount of atmospheric deposited water in the 2 and 3 mm 
ranges. It should be noted that equipment malfunctions appeared 

 

Figure 2. The principle of measurement by the method of vertical cuts. The 
left side shows a typical temperature distribution in the troposphere with 
respect to height (the so-called temperature profile). In the middle - a typical 
distribution of humidity in height. These profiles are subject to significant 
seasonal and daily changes, in fact, from them it is possible to calculate the 
amount of precipitated water and extrapolate it to absorption. On the right 
are the zenith angles (that is, the number of atmospheres) by which the 
radiometer approximates the brightness temperature profile [16].  

 

Figure 3. The atmospheric absorption time series obtained from January 
2015 to November 2020 on the Suffa plateau during the entire period in the 
2 mm range 



 

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in 2018, and the data obtained were very different from the 
previous values of atmospheric parameters. Therefore, when 
calculating atmospheric parameters, the data of 2018 were 
discarded. 

The statistical distribution of atmospheric absorption and the 
amount of precipitated water is shown in Figure 4. The median 
value of atmospheric absorption over the entire observation 
period was 0.13 and 0.11 Nep for the 2 mm and 3 mm radio 
range, respectively. The median value of the atmospheric amount 

of precipitable water for the entire period of observations in the 2 
mm radio band was 4.96 mm, and for the 3 mm band, 9.25 mm. 

The sesonal trends are shown in Table 1, which reports the 
average monthly values of atmospheric absorption (Abs) and the 
amount of precipitable water vapor (PWV) computed after 
merging different years. As can be seen from the data, in the 
2015-2020 period, the average monthly values of atmospheric 
absorption and the amount of deposited water on the Suffa 
plateau remain fairly stable. The main range of changes in 
atmospheric absorption and the amount of deposited water lies 
within 0.11-0.19 Nep and 4.84-7.40 mm for the 2 mm range of 

the radio wave spectrum, and for the 3 mm range ‒ 0.11-
0.14 Nep and 8.81 -13.38 mm, respectively. 

For a visual representation of the statistics of atmospheric 
parameters and its trend of change, the seasons were chosen 
according to the principle of weather conditions: November, 
December, January and February belong to the winter season; 
the transitional season includes March, April, September and 
October, the summer season - May, June, July and August. In the 
winter season, the average value of atmospheric absorption is less 
than 0.10 Nep, in the transitional season it is less than 0.12 Nep, 
and in the summer season it is more than 0.12 to 0.15 Nep, for 
the 3 mm range. For the 2 mm range in the winter season, the 
average value of atmospheric absorption is less than 0.12 Nep, in 
the transitional season it is less than 0.14 Nep, and in the summer 
season it is more than 0.14 to 0.15 Nep.  

The temporal dynamics of precipitated water in January and 
July are characteristic of extreme climate conditions. The average 
value of deposited water in January is about 4.84 mm for the 2 
mm range, 10.0 mm for the 3 mm range, and in July 7.40 and 
13.38 mm for the 2 and 3 mm ranges, respectively. 
The diurnal variations of the deposited water in the summer 
period are more significant than in winter. On some nights in 
December and January, the amount of precipitated water drops 
to a minimum of about 2 mm, in summer it rises to 12 mm. 

4. CONCLUSIONS 

Based on this study, it can be concluded that over a six-year 
period of time, the atmospheric parameters on the Suffa plateau 
remain fairly stable. The values of atmospheric absorption and 
deposited water presented here correspond to the values of the 
entire thickness of the atmosphere at the zenith. Measurements 
of atmospheric parameters on the Suffa Plateau showed that the 
value of atmospheric absorption at the zenith at a wavelength of 
3 mm, sometimes for several is was within 0.06–0.08 Nep, and 
at a wavelength of 2 mm - within 0.08-0.10 Nep. At shorter time 
intervals, for several hours, the absorption of the 3 mm wave 
sometimes drops to 0.06–0.08 Nep, and at a wavelength of 2 mm 
to 0.05–0.06 Nep. Such cases occur in the winter. The amount 
of precipitated water for several days is in the range of 1.6-
2.0 mm. 

They can be reduced to parameters at any angle, as well as 
extrapolated to any height, taking into account the standard 
atmosphere model.  

REFERENCES 

[1] Yu. P. Kalmykov, S. V. Titov, Application of the method of 
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Figure 4. Statistical distribution of atmospheric absorption (on top) and 
amount of deposited water (below) on the Suffa plateau, calculated for the 
radio wave bands of 2 and 3 mm, from January 2015 to November 2020. The 
y-axis of the histogram is on the right, the cumulative distribution is on the 
left. 

Table 1. Monthly average values of atmospheric absorption and integral 
amount of deposited water from January 2015 to December 2020. 

Months 
Absorption 

3 mm 
Absorption 

2 mm 
PWV 
3 mm 

PWV 
2 mm 

January 0,11 0,11 8,81 4,84 

February 0,12 0,14 10,44 5,05 

March 0,12 0,15 11,42 5,89 

April 0,13 0,16 12,22 6,22 

May 0,14 0,18 12,82 7,21 

June 0,14 0,19 13,26 7,27 

July 0,14 0,17 13,38 7,40 

August 0,14 0,16 13,25 7,28 

September 0,14 0,14 12,57 7,09 

October 0,13 0,14 12,05 6,62 

November 0,12 0,12 11,11 5,56 

December 0,12 0,11 9,25 4,69 

Mean 0,12 0,14 11,30 5,91 



 

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https://doi.org/10.1364/ao.29.001979
https://ui.adsabs.harvard.edu/link_gateway/2004PASA...21..256C/doi:10.1071/AS03018
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