1.3 TROPOSPHERIC EFFECTS Radiowave

1.3 TROPOSPHERIC EFFECTS

Radiowave transmissions on Earth-space links are subject to major atmospheric degradations in
the troposphere, extending from the surface of the earth to about 20 km in altitude. The
troposphere, and the gaseous constituents (oxygen, water vapor) and hydrometeors (rain, snow,
cloud particles, etc.) it contains, can impair satellite communication links in one or more of the
following ways;

o a reduction in signal amplitude (attenuation),
o depolarization of the radiowave,
o an increase in thermal noise (radio noise) in the system,

and, for certain special conditions, particularly for low elevation angle systems,

o amplitude and phase scintillation,
o a change in angle-of-arrival of the signal,

and, for wideband transmissions,

o amplitude and phase dispersion.

Each of these effects is introduced and briefly discussed below. The appropriate sub-sections
where further information can be found in Section 1 of the Handbook are listed with the
description.

Attenuation. Attenuation is the term used to describe a reduction in signal amplitude caused by
constituents of the Earth’s atmosphere, or conditions in the atmosphere, which are present in the
transmission path. Attenuation is caused by the gaseous components of the atmosphere (always
present), and by hydrometers (clouds, rain, fog, and snow) which can be present for certain
periods of time. Hydrometers are the products formed by the condensation of atmospheric water
vapor. Hydrometer attenuation experienced by a radiowave involves both absorption and
scattering processes.

Gaseous Attenuation is the reduction in signal amplitude caused by the gaseous constituents of
the Earth's atmosphere which are present in the transmission path. Gaseous attenuation is an
absorption process, and the primary constituents of importance at space communications
frequencies are oxygen and water vapor. Gaseous attenuation increases with increasing
frequency, and is dependent on temperature, pressure, and humidity. (Section 1.3.1)

Rain attenuation can produce major impairments in space communications, particularly in the
frequency bands above 10 GHz. Because of its severity and unpredictability, rain attenuation
rightly receives the most attention in the satellite system design process for frequencies above 10
GHz. (Section 1.3.3)


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Cloud and fog attenuation is much less severe than rain attenuation, however it must be
considered in link calculations because it is normally present for a much larger percentage of the
time than rain. (Section 1.3.2)

Dry snow and ice particle attenuation is usually so low that it is unobservable on space
communications links operating below 50 GHz.

In all of the factors affecting satellite communications in the troposphere, attenuation is
increased significantly with low elevation angles, where the total path through the troposphere is
longer, and the effects can by more severe. Virtually all prediction models for troposphereic
effects require elevation angle as a critical input parameter


Depolarization. Depolarization refers to a change in the polarization characteristics of a
radiowave caused by a) hydrometers, primarily rain or ice particles, and b) multipath
propagation. A depolarized radiowave will have its polarization state altered such that power is
transferred from the desired polarization state to an undesired orthogonal polarized state,
resulting in interference or crosstalk between the two orthogonal polarized channels. Rain and
ice depolarization can be a problem in the frequency bands above about 12 GHz, particularly for
`frequency reuse' communications links that employ dual independent orthogonal polarized
channels in the same frequency band to increase channel capacity. Multipath depolarization is
generally limited to very low elevation angle space communications, and will be dependent on
the polarization characteristics of the receiving antenna. (Sections 1.3.3, 1.3.4)

The effect of rain depolarization interference is fundamentally different from the amplitude
reduction or noise increase propagation effects in that increasing the link power does not reduce
the interference. Rain can cause scattering of electromagnetic energy out of the line-of-sight,
resulting in increased leakage of uplink power into the receive beam of an adjacent satellite, or
between terrestrial line-of-site systems and low-angle Earth station antennas. A power increase
will raise the level of the desired and the interfering signals simultaneously.

Scintillation. Earth stations operating at low elevation angles are subject to scintillation caused
by tropospheric turbulence. This consists of fast random fluctuations in the amplitude and phase
of the signal. The effects of scintillations on the channel depend on the receiver antenna
characteristics, type of modulation used and the receiver performance. The power spectrum of
the fluctuation falls off quickly with increasing frequency, so the effects should be expected to
be primarily brief signal drop-outs or losses of synchronization, rather than any actual
modulation of the information-carrying waveforms. (Section 1.3.5)

Angle of Arrival. Angle of Arrival describes a change in the direction of propagation of a
radiowave caused by refractive index changes in the transmission path. Angle of arrival
variations are a refraction process, and results in an apparent shift in the location of satellite
position. (Section 1.3.6)


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Dispersion. A change in the frequency and phase components across the bandwidth of a
radiowave, caused by a dispersive medium is described as dispersion or frequency dispersion. A
dispersive medium is one whose constitutive components (permittivity, permeability, and
conductivity) depend on frequency (temporal dispersion) or wave direction (spatial dispersion).1
The coherence bandwidth is defined as the upper limit on the information bandwidth or channel
capacity that can be supported by a radiowave, caused by the dispersive properties of the
atmosphere. Another degradation affiliated with dispersion is termed antenna gain degredation.
Antenna gain degradation is an apparent reduction in the gain of a receiving antenna caused by
amplitude and phase dispersion across the aperture. This effect can be produced by intense rain,
however, it is usually only observable with very large aperture antennas at frequencies above
about 30 GHz and for very long path lengths through the rain, i.e. low elevation angles. (Section
1.3.7)

Wet Surface Effects. Recent measurements with the NASA Advanced Technology Satellite
(ACTS) have highlighted another significant degradation for satellite communications links,
related to rain attenuation. The presence of water on the surfaces of the antenna (reflector, feed
cover) can add additional attenuation, above that caused by rain in the path itself. This effect is
heavily dependent on antenna surface characteristics and on the material used. (Section 1.3.8)
Preliminary prediction models are available to evaluate the quantitative effects of the problem.
(Section 2.2.7)

Radio Noise. Radio noise describes the presence of undesired signals or power in the frequency
band of a communications link, caused by natural or man-made sources. Radio noise can
degrade the noise characteristics of receiver systems and affect antenna design or system
performance. The primary natural noise sources for frequencies above about 1 GHz are
atmospheric gases (oxygen and water vapor), rain, clouds, and surface emissions. Man-made
sources include other space or terrestrial communications links, electrical equipment, and radar
systems. Extraterrestrial cosmic noise must only be considered for frequencies below about 1
GHz. The classical laws of physics and black body radiation specify that anything that absorbs
electromagnetic energy radiates it as well. The energy radiated by tropospheric absorbing media
(oxygen, water vapor, rain drops, cloud particles, etc.) is incoherent and broadband. It is
received by the receive antenna along with the desired signal, and appears at the receiver output
as thermal noise - indistinguishable from the thermal noise generated in the receiver front end.
The effect of the received noise energy is accounted for by adding "radio noise" (also referred to
as sky noise or atmospheric noise) to the receiver system noise temperature. The radio noise
temperature is directly related to the attenuation that the absorbing medium produces. (Section
1.4)

1 Note: The term dispersion is also used to denote the differential delay experienced across the
bandwidth of a radiowave propagating through a medium of free electrons, such as the
ionosphere or a plasma.

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All of the tropospheric degradations described above produced on a satellite will be dependent
on a number of system parameters and path conditions. Propagation impairments caused by the
troposphere are generally dependent on the following system parameters:

Operating Frequency
With the exception of signal attenuation by gaseous absorption lines, the severity of
tropospheric impairments increases with frequency.

Antenna Elevation Angle and Polarization
The length of the part of the propagation path passing through the troposphere
varies inversely with elevation angle. Accordingly, propagation losses, noise, and
depolarization also increase with decreasing elevation angle. Rain attenuation is
slightly polarization-sensitive. Depolarization is also polarization-sensitive, with
linear horizontal and circular polarization being the most susceptible.

Earth Station Altitude
Because less of the troposphe