Rain Rate and Rain Attenuation Over Millimeter Waves in Tropical Regions Based on Real Measurements

This paper presents the results of direct rain attenuation measurements carried out on four experimental microwave links, installed at UTM, Malaysia. The links operate at frequencies of 15, 22, 26, and 38 GHz and the cumulative distribution function for different rain rates have been generated from the measured 4-year rain gauge data. The experimentally measured attenuation data have been compared with International Telecommunication Unior-R rain attenuation predictions; and it has been found that the latter have underestimated the measured values, especially at higher rain rates. The deviations have been modeled as a function of rain rate exceedances R%p. It is hoped that the study will provide useful information for estimation of rainfall attenuation on microwave links in tropical regions that have similar situation to Malaysia.

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Investigation of time diversity gain for earth to satellite link using rain rate gain

Bulletin of Electrical Engineering and Informatics ◽

10.11591/eei.v8i3.1512 ◽

2019 ◽

Vol 8 (3) ◽

pp. 951-959

Author(s):

Md. Moktarul Alam ◽

Islam Md. Rafiqul ◽

Khairayu Badron ◽

Farah Dyana A. R. ◽

Hassaan Dao ◽

...

Keyword(s):

Communication Systems ◽

Rain Rate ◽

Satellite Communications ◽

Rain Attenuation ◽

Diversity Gain ◽

Potential Candidate ◽

Tropical Regions ◽

Frequency Bands ◽

Time Diversity ◽

One Year

The utilization of satellites for communication systems has expanded considerably in recent years. C and Ku-bands of frequencies are already congested because of high demand. Future directions of satellite communications are moving towards Ka and V-bands. Earth to satellite communications are moving towards higher frequency bands in future which are more sensitive to environment. Rain causes severe degradation in performances at higher frequency bands specially in tropical regions. Several mitigation techniques are proposed to design reliable system. Time diversity is one of the potential candidate for it. However, time diversity analysis requires measured rain attenuation data. For future high frequency link design those data are not available at most of the places. This thesis proposes a method to utilize 1-minute rain rate to analyze time diversity technique at any desired frequency. This paper proposes a method to utilize 1-minute rain rate to analyse time diversity rain rate gain. In proposed method, it is assumed that rain rate gain with delay can represent rain attenuation gain with delay for same period of time at same location. The characteristics of rain rate and rain attenuation almost same because the attenuation causes due to rain. One year measured rain rate in Malaysia is used to predict rain rate gain. The measured gain at 12.225 GHz signal is compared with that predicted by ITU-R based on rain rate measurement and is found good agreement. Hence it is recommended that the time diversity gain can be predicted using measured rain rate for any desired frequencies.

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Performance evaluation of some rain attenuation prediction models at coastal locations at 12 and 40 GHz

Global Journal of Earth and Environmental Science ◽

10.31248/gjees2021.095 ◽

2021 ◽

Vol 6 (2) ◽

pp. 27-37

Author(s):

Abayomi Isiaka O. Yussuff ◽

◽

Kabir Momoh ◽

Keyword(s):

Rain Rate ◽

Prediction Models ◽

Service Providers ◽

Service Level ◽

Rain Attenuation ◽

Rainfall Data ◽

Integration Time ◽

Tropical Regions ◽

Attenuation Models ◽

The Tropics

This work concerns the evaluation of the performances of some selected rain attenuation models at two different locations in Lagos, Nigeria at 12 and 40 GHz. Scarcity of rainfall data in the tropical regions resulted in abysmal research efforts into the causes and solutions to satellite signal outages, this was further exacerbated by the convective tropical rain precipitations. The globally adopted ITU-R model, had been declared unsuitable for predicting rain attenuation in the tropics by several researchers in the literature. Two-year (January 2016 to December 2017) local rainfall data were sourced from the Nigerian Meteorological Services (NIMET) for two coastal stations (Ikeja and Oshodi). Rain attenuation exceeded for rain rate at 0.01% of the time, was computed after the 1-hour rain rate integration time which was sourced from NIMET was converted to 1-minute integration time. Attenuation exceeded for other percentages of time were also obtained using statistical interpolation and extrapolation methods. The collected data were tested with ITU-R, SST, SAM, DAH and Silva Mello et al. For Ikeja at 12 GHz, the SST was observed to closely match the measurement attenuation at 0.01%≤p≤1% of time exceeded; closely followed by Silver Mello. For Oshodi also at 12 GHz, SST intersected with the measured attenuation at 0.01%≤p≤0.03%, and p=0.1% of time. However, at 40 GHz, all the prediction models performed poorly by underestimating the measurement for Ikeja, although SST showed the best effort. The SST model matched the measurement, especially at p=0.03% and p=0.5% for Oshodi at 40 GHz, closely followed by Silva Mello which matched the measurement at p=0.05% and p=0.1%, while ITU-R, SAM and DAH largely underestimated the measurement. The SST was therefore affirmed the overall best performed rain attenuation prediction model for both stations at both frequency bands; closely followed by the Silva Mello. ITU-R, SAM and DAH on the other hand performed poorly. The findings arising from this work could present useful information to satellite equipment designers and manufacturers, while at the same time ensuring that service providers conform to the required service level agreements

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Estimation of attenuation due to rain within Ka and Ku bands in Oyo State of Nigeria

FUOYE Journal of Engineering and Technology ◽

10.46792/fuoyejet.v6i1.596 ◽

2021 ◽

Vol 6 (1) ◽

Author(s):

Hammed O Busari ◽

Olaosebikan A Fakolujo

Keyword(s):

Satellite Communication ◽

Rain Rate ◽

Attenuation Factor ◽

Rain Attenuation ◽

Attenuation Effect ◽

Effective Utilization ◽

Tropical Regions ◽

Communication Signal ◽

Significant Attenuation ◽

Propagation Modelling

Rain-induced attenuation of microwaves poses a serious challenge to signal availability beyond 10 GHz frequencies. The challenges are even more pronounced in the subtropical and tropical regions with high intensities of rain which is more accompanied with thunderstorms. Nigeria has an equatorial and tropical climate, which is identified by controlling rainfall. Rain is the significant attenuation factor of various communication signal above 10 GHz frequencies. Therefore, for effective utilization of the microwave bandwidth during rainfall, it is required to form the correlation between this attenuation effect and the bandwidth at various rainfall rate and frequencies at a particular interest location. Therefore , using propagation modelling, the point rainfall and rain effects for frequencies was concurrently considered between 11 and 40 GHz (i.e. Ku, and Ka) for satellite communication service on earth-space path at Ibadan in Oyo state , Nigeria by using rainfall data for the period of five (5) years (January 2014 to December 2019).Keywords- Rain Attenuation, Rain Rate, Bandwidth, Propagation Modelling

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Evaluation of real time rain-rate on downlink satellite signal attenuation in Abuja, Nigeria

EDUCATUM Journal of Science, Mathematics and Technology ◽

10.37134/ejsmt.vol7.1.4.2020 ◽

2020 ◽

Vol 7 (1) ◽

pp. 29-38

Author(s):

Alhassan Tijani ◽

Samson D. Yusuf ◽

Umar Ibrahim ◽

Abdulmumini Z. Loko ◽

Abdullahi A. Mundi

Keyword(s):

Satellite Communication ◽

Rain Rate ◽

Signal Transmission ◽

Rain Attenuation ◽

Distribution Functions ◽

Cumulative Distribution ◽

Natural Phenomenon ◽

Signal Attenuation ◽

Tropical Regions ◽

High Attenuation

Natural phenomenon and other human activities in the atmosphere have caused serious variations in rainfall which leads to rain-rates that has resulted in the mitigation of signal transmission in satellite communication. This is due to absorption and scattering of the radio waves, resulting in the reduction of the overall link availability. In this study, the cumulative distribution functions (CDFs) for the predicted rain rate and rain attenuation in Abuja, Nigeria was evaluated using the Moupfouma and Chebil models purposely designed for tropical regions. One year data of signal attenuation and amount of rainfall in the study area for 2018 was collected from Nigerian Communication Satellite limited (NIGECOMSAT) and Nigeria Metrological Center (NiMET). The Ajayi (ITU-R P) models alongside with relevant statistics were employed for evaluation of the rain attenuation in the study area. Results show that the highest rainfall value with mean of 128.07 mm was recorded in August while the lowest value 01.87 m was recorded in November. The estimated value of rain-rate in the study area were 1.95 mm/hr and 5.57 mm/hr in August and September with high attenuation value of 11.01dB – 19.67dB and 15.84dB – 18.64dB both on C – band and Ku – band. The result Show that, attenuation due to rain in the frequency above 10GHz is much higher than that for frequency of 4GHz. Therefore, as the size of the rain drop approaches the wavelength of the signal, the more it absorbs its strength and the higher the rain rate attenuation on signal. The result is useful for designing highly reliable microwave links in the study area.

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Rain attenuation statistics over 5G millimetre wave links in Malaysia

Indonesian Journal of Electrical Engineering and Computer Science ◽

10.11591/ijeecs.v14.i2.pp1012-1017 ◽

2019 ◽

Vol 14 (2) ◽

pp. 1012 ◽

Cited By ~ 2

Author(s):

Mustafa Ghanim ◽

Manhal Alhilali ◽

Jafri Din ◽

Hong Yin Lam

Keyword(s):

Path Length ◽

Rain Rate ◽

Prediction Models ◽

Wireless Systems ◽

Rain Attenuation ◽

Wave Band ◽

Short Path Length ◽

Millimetre Wave ◽

Tropical Regions ◽

Major Disadvantage

Millimetre wave band is a solid contender to be utilized for the future 5G wireless systems deployment. Rain-induced attenuation is a major disadvantage at these frequencies. This paper presents statistics of rain-induced attenuation and rainfall data for two years of horizontally polarized links propagating at 38 GHz and 26 GHz over a terrestrial path link of 301 meters. From the analysed datasets, a rain rate around 116 mm/h exceeded at 0.01% of the time of an average year, while the links recorded 16 and 9.5 dB at the same percentage of time for 38 and 26 GHz respectively. The study aims to identify the prediction model that deliver most reasonable predictions for 5G links operating in Malaysian tropical climate. ITU-R P.530-17, Mello’s, and Ghiani’s models were all examined. Using ITU-R model, relative error margins of around 3.8%, 30% and 49.7% alongside 22.3, 9.5, 33% were obtained in 0.1%, 0.01% and 0.001% of the time for 26 and 38 GHz respectively. Curiously, ITU-R model demonstrates better predictions to measured rain attenuation with lower error probability. This study highlights the need for new prediction models for short path-length 5G links and helps to improve the design of terrestrial links operating at millimetre wave frequencies in tropical regions.

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Analysis of rain fade slope for terrestrial links

Indonesian Journal of Electrical Engineering and Computer Science ◽

10.11591/ijeecs.v18.i2.pp896-902 ◽

2020 ◽

Vol 18 (2) ◽

pp. 896

Author(s):

Jalel Chebil ◽

Al-Hareth Zyoud ◽

Mohamed Hadi Habaebi ◽

Islam Md. Rafiqul ◽

Hassan Dao

Keyword(s):

Standard Deviation ◽

Prediction Model ◽

Rain Attenuation ◽

Measured Data ◽

Rate Of Change ◽

Tropical Regions

Rainfall can cause severe degradation to the operation of microwave links working with frequencies above 10 GHz. Many studies have investigated this problem, and one of the factors that attract the attention of researcher is rain fade slope which is the rate of change of rain attenuation. The focus of this study is on rain fade slope for terrestrial links and it is based on measurement conducted in Malaysia. This paper investigates the characteristics of the measured rain fade slope distribution for various attenuation levels. Then, the ITU-R model for rain fade slope is compared with the corresponding statistics obtained from the measured data. Significant discrepancies have been observed since the ITU-R prediction model does not fit the measured fade slope distribution for many attenuation levels. It is recommended to modify the expression of the standard deviation in the ITU-R model when implemented in tropical regions.

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Rain attenuation of millimetre wave above 10 GHz for terrestrial links in tropical regions

Transactions on Emerging Telecommunications Technologies ◽

10.1002/ett.3450 ◽

2018 ◽

Vol 29 (8) ◽

pp. e3450 ◽

Cited By ~ 4

Author(s):

Ibraheem Shayea ◽

Tharek Abd. Rahman ◽

Marwan Hadri Azmi ◽

Arsany Arsad

Keyword(s):

Rain Attenuation ◽

Millimetre Wave ◽

Tropical Regions

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Investigation of HAPs Propagation Channel for Wireless Access in a Tropical Region at Ka-Band

International Journal of Electrical and Computer Engineering (IJECE) ◽

10.11591/ijece.v7i3.pp1204-1211 ◽

2017 ◽

Vol 7 (3) ◽

pp. 1204

Author(s):

Felix Obite ◽

Jafri Din ◽

Kamaludin Mohammad Yusof ◽

Basliza M. Noor

Keyword(s):

Fading Channels ◽

Channel Model ◽

Rain Attenuation ◽

Wireless Access ◽

Rician Fading ◽

Communication Link ◽

Propagation Channel ◽

Ka Band ◽

Tropical Regions ◽

Budget Analysis

In the last few years, High Altitude Platforms (HAPs) have attracted considerable effort due to their ability to exploit the advantages of satellite and terrestrial-based systems. Rain attenuation is the most dominant atmospheric impairment, especially at such frequency band. This paper addresses the modelling of rain attenuation and describes a propagation channel model for HAPs at Ka-band to provide efficient and robust wireless access for tropical regions. The attenuation due to rain is modeled based on three years measured data for Johor Bahru to estimate the actual effect of rain on signals at Ka band. The radio propagation channel is usually characterized as a random multipath channel. Specifically, a statistical derivation of probability distribution function for Rayleigh and Rician fading channels are presented. The model consists of multiple path scattering effects, time dispersion, and Doppler shifts acting on the HAPs communication link. Simulation results represent the fading signal level variations. Results show perfect agreement between simulation and theoretical, thereby conforming to the multipath structures. The information obtained will be useful to system engineers for HAPs link budget analysis in order to obtain the required fade margin for optimal system performance in tropical regions.

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Analysis of Selected Earth-Space Rain Attenuation Models for a Tropical Station

Indonesian Journal of Electrical Engineering and Computer Science ◽

10.11591/ijeecs.v3.i2.pp383-391 ◽

2016 ◽

Vol 3 (2) ◽

pp. 383 ◽

Cited By ~ 1

Author(s):

A. I. O. Yussuff

Keyword(s):

Prediction Models ◽

Measurement Data ◽

Daily Rainfall ◽

Rain Attenuation ◽

Propagation Path ◽

Tropical Regions ◽

Earth Space ◽

Budget Analysis ◽

Link Budget ◽

Attenuation Models

The restrained use of millimeter bands is due to severe rain attenuation. Attenuation is caused when rain cells intersects radio wave’s propagation path; resulting in deep fades. The effect of rainfall is more severe in tropical regions characterized by heavy rainfall intensity and large raindrops; hence, rain attenuation analyses are essential to study rain fade characteristics for use in earth-space link budget analysis, for outage prediction resulting from rain attenuation. Tropical regions are particularly challenged with signal outage, necessitating the formulation and development of suitable prediction model(s) for the region. Therefore, extensive knowledge of the propagation phenomena mitigating system availability and signal quality in these bands are required. Daily rainfall data were collected from the Nigerian Meteorological Services for Lagos for spanning January to December 2010. Results showed that although, the ITU-R model out-performed the other prediction models under consideration, none of prediction models matched the measurement data.

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