The effect of atmosphere on earth-space radiowave propagation studies of tropical satellite communication in nigeria

 

Table Of Contents


  • <p> </p><p>Title page i<br>Certification ii<br>Declaration iii<br>Acknowledgement iv<br>Table of Content v<br>Abstract ix<br>

Chapter ONE

INTRODUCTION

  • <br>INTRODUCTION<br>
  • 1.1Background of the study 1<br>
  • 1.2Statement of the Problem 2<br>
  • 1.3Rationale for the study 3<br>
  • 1.4Aims and Objectives of the study 4<br>

Chapter TWO

LITERATURE REVIEW

  • <br>LITERATURE REVIEW<br>
  • 2.1Attenuation by Rain 5<br>2.
  • 1.1Characteristics of Rainfall in tropical region 6<br>2.
  • 1.2Raindrop by size 6<br>2.
  • 1.3Existing Rain attenuation models 7<br>2.1.
  • 3.1Overview 7<br>vii<br>2.
  • 1.4Methods of Rain attenuation measurements 12<br>
  • 2.2Attenuation by Cloud 13<br>2.
  • 2.1Cloud data sources 15<br>2.
  • 2.2Existing Cloud attenuation models 16<br>2.2.
  • 2.1Overview 16<br>
  • 2.3Attenuation by Atmospheric Gases 19<br>
  • 2.4Tropospheric Scintillation 21<br>2.
  • 4.1Amplitude Scintillation Prediction Models 22<br>

Chapter THREE

RESEARCH METHODOLOGY

  • <br>EXPERIMENTAL MODEL<br>
  • 3.1Processing of Rain data 24<br>3.
  • 1.1Isotherm height and Rain height 24<br>3.
  • 1.2Calculation of long-term rain attenuation statistics from point rainfall rate 25<br>
  • 3.2Processing of Cloud data 28<br>3.
  • 2.1Procedure for evaluation of SVD, TCC and IWVC 28<br>3.2.
  • 1.1Surface Water Vapour Density, ρ (SVD) 28<br>3.2.
  • 1.2Integrated Water Vapour Content (IWVC) 29<br>viii<br>3.2.
  • 1.3Total columnar content of liquid water in clouds (TCC) 30<br>3.
  • 2.2Procedure for Evaluation of Cloud Attenuation 32<br>3.2.
  • 2.1Specific Cloud attenuation coefficient 32<br>
  • 3.3Processing of Gaseous Data 34<br>3.
  • 3.1Gaseous Specific Attenuation 35<br>3.3.
  • 1.1Dry air Attenuation (dB/km) 35<br>3.3.
  • 1.2Water vapour attenuation (dB/km) 37<br>
  • 3.4Processing of tropospheric Scintillation Data 38<br>3.
  • 4.1Procedure for evaluating the input parameters 38<br>

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • <br>RESULTS AND DISCUSSIONS<br>
  • 4.1Results of Rain Attenuation 41<br>4.
  • 1.1Comparing the Rain Attenuation Experimental Model with the Lognormal<br>Distribution Modeling by Ajayi and Olsen (2000). 45<br>
  • 4.2Results of Cloud Attenuations 47<br>4.
  • 2.1Comparing the Cloud Attenuation Experimental Model with the ITU-R Model. 51<br>
  • 4.3Results of Gaseous Attenuation. 52<br>ix<br>4.
  • 3.1Comparing the Gaseous Attenuation Experimental Model with the ITU-R Model. 56<br>
  • 4.4Results of Tropospheric Scintilliation. 58<br>4.
  • 4.1Comparing the Tropospheric Scintillation Experimental Model with the<br>ITU-R Model. 62<br>
  • 4.5Results for Combined Attenuation. 63<br>

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • <br>SUMMARY AND CONCLUSIONS<br>
  • 5.1Rain attenuation at Frequencies between 10 to 50 GHz 67<br>
  • 5.2Cloud Attenuation at Frequencies between 10 to 50 GHz 67<br>
  • 5.3Gaseous Attenuation Study at Frequencies between 10 to 50 GHz 68<br>
  • 5.4Tropospheric Scintillation Study at Frequencies between 10 to 50 GHz 68<br>
  • 5.5Combined Attenuation Study at 0.01% Unavailability of an Average Year for<br>Frequencies between 10 to 50 GHz 68<br>
  • 5.6Conclusion and Recommendations 69<br>REFERENCES 71<br>APPENDIX 76<br>x</p><p>&nbsp;</p> <br><p></p>

Project Abstract

<p> Among other atmospheric region, ionosphere, which is the ionized region of the atmosphere, is considered to impose serious limitation on radio wave transmission while the effect of other layers, more especially, the troposphere is often treated as negligible. At higher frequency, radio waves pass through the ionosphere and are attenuated due to the free electrons present in it. However, recent studies have shown that while the ionospheric disturbances can be predicted on a global scale, tropospheric disturbances depend on geographic location due to dependence of local meteorology on surface topography and other specific location weather forcing. A number of models has been used by many researchers in the investigating of atmospheric attenuation. The objective of this thesis is to discuss the atmospheric effects on high frequency radio waves between 10 and 50 GHz propagating on earth-space in the troposphere for 12 locations in Nigeria, investigating the attenuation and losses it may come across like attenuation due to atmospheric gases, rain, clouds and tropospheric scintillation and comparing them with the model used by the researchers. Two standard elevations angle of and were used in the computation of the propagation impairment for the 12 location <br></p>

Project Overview

<p> </p><p>RODUCTION<br>1.1 Background of the study<br>Satellite communication is normally thought of as a robust means of communication, not sensitive to environment impacts. This perception is not totally accurate. Satellite communication can be and is affected by the environment in which it operates. Space environment effects on satellite communication can be separated into (1) effects on the space element (i.e. the satellite), (2) effects on the ground element (i.e. the Earth station), and (3) effects on the signals propagating through the Earth’s lower and upper atmosphere. The propagating signal may be affected by its passage through the ionosphere (upper atmosphere) or the troposphere (lower atmosphere). These effects depend significantly on frequency, but include signal absorption, scintillation, Faraday rotation and bandwidth decoherence. Geographic location and signal propagation path can also determine the extent to which the signal is affected. The ionosphere is a region of the upper atmosphere that extends from 70 to 500 km in altitude. It is a region where some of the atoms have had their outer electrons removed by extreme ultra-violet (EUV) and X-ray radiation coming from the sun. The atmosphere is thus said to be partially ionized – hence the name, ionosphere. The ionosphere usually consists of four layers but two layers are more important in radio propagation.<br>Troposphere is the lower most layer of the atmosphere adjacent to the earth’s surface and contains approximately 80% of the atmosphere’s mass and 99% of its water vapour and aerosols. This layer extends up to about 14-17 km in the tropical region and becomes shallower towards polar region. It is the layer that determines the daily weather cycle of the earth. Within the<br>2<br>troposphere there is generally a gradual fall in temperature with increasing altitude and most of the turbulent mixing occurs in this region. The refractive index of the air in the atmosphere plays a dominant role in microwave signal propagation over earth-space path. Tropospheric weather conditions, occurring in the lower 10 km of the atmosphere, can also cause losses in signals propagating between satellite and ground stations. Beam spreading is more pronounced at (Very High Frequency) VHF and (Ultra High frequency) UHF. Water vapour is particularly damaging to signals above about 2GHz, causing absorption of signals which becomes greater as frequency increases. K-band signals (10-20 GHz) are particularly susceptible, and precipitation in the vicinity of satellite ground stations can cause total loss of signal. Again, signals with low elevations are more affected than those propagating near the zenith, because the wave has to follow a longer path through the atmosphere. At frequencies above 20 GHz, we start to encounter resonant absorption at specific frequencies. Oxygen in particular, will absorb electromagnetic energy only at certain well-defined frequencies. These frequencies correspond exactly to the energies required to lift the oxygen atoms into higher energy states. Satellite communication links are designed to avoid these well-known frequency bands<br>1.2 Statement of the problem<br>Radiowave propagating between terrestrial links and earth-space links are adversely affected by atmospheric gases, rain, clouds and tropospheric scintillation. The problems become more acute for systems operating at frequencies above 10 GHz. Nigeria is located in the tropics unlike the temperate environments such as Europe and North America. The effects of the troposphere on radiowave propagation will be most severe in the tropics because of high frequency of occurrence of rainfall, high temperature, high relative humidity, and high rain intensities which<br>3<br>lead to a more severe signal attenuation and outage than what is experienced in the temperate region.<br>1.3 Rationale for the study<br>There is very little information on propagation studies on earth-space communication links in Nigeria. Where there is information, there are only few that cover the effect of atmosphere. The one that was carried out in Ilorin was to experiment the effect of rain on Ku band frequency and satellite communication in the tropical region (Adimula, et.al.,2005). The present study is therefore aimed at investigating the effects of rain, cloud, gases and tropospheric scintillation on earth-space path at 12 stations in Nigeria by using satellite data for the period 2009 to 2013.<br>1.4 Aims and objectives of the study<br>The aim is to investigate the effect of attenuation on earth-space path and the following steps were taken in achieving the objectives of the study:<br>1. Compute some propagation impairments relevant to fixed satellite communication at elevation angles of 5 , 55 in the 12 locations in Nigeria.<br>2. Locate the highest and the lowest places affected by propagation impairments year round by dividing the country into six zones (namely SW, SE, SS, MB, NW and NE) and conduct a comparative analysis of the results.<br>3. Finally, compare the result to the model used by other researchers and verify if they match well or not.</p><p>&nbsp;</p> <br><p></p>

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