2-36distances are possible because of the different densities and refractive qualities of warm and cool air. Thesudden change in density when a radio wave enters the warm air above a duct causes the wave to berefracted back toward Earth. When the wave strikes the Earth or a warm layer below the duct, it is againreflected or refracted upward and proceeds on through the duct with a multiple-hop type of action. Anexample of the propagation of radio waves by ducting is shown in figure 2-25.Figure 2-25.-Duct effect caused by temperature inversion.Q42. How do raindrops affect radio waves?Q43. How does fog affect radio waves at frequencies above 2 gigahertz?Q44. How is the term "temperature inversion" used when referring to radio waves?Q45. How does temperature inversion affect radio transmission?TROPOSPHERIC PROPAGATIONAs the lowest region of the Earth's atmosphere, the troposphere extends from the Earth's surface to aheight of slightly over 7 miles. Virtually all weather phenomena occur in this region. Generally, thetroposphere is characterized by a steady decrease in both temperature and pressure as height is increased.However, the many changes in weather phenomena cause variations in humidity and an uneven heating ofthe Earth's surface. As a result, the air in the troposphere is in constant motion. This motion causes smallturbulences, or eddies, to be formed, as shown by the bouncing of aircraft entering turbulent areas of theatmosphere. These turbulences are most intense near the Earth's surface and gradually diminish withheight. They have a refractive quality that permits the refracting or scattering of radio waves with shortwavelengths. This scattering provides enhanced communications at higher frequencies.Recall that in the relationship between frequency and wavelength, wavelength decreases asfrequency increases and vice versa. Radio waves of frequencies below 30 megahertz normally havewavelengths longer than the size of weather turbulences. These radio waves are, therefore, affected verylittle by the turbulences. On the other hand, as the frequency increases into the vhf range and above, thewavelengths decrease in size, to the point that they become subject to tropospheric scattering. The usablefrequency range for tropospheric scattering is from about 100 megahertz to 10 gigahertz
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Wave propagation is the way in which waves spread and travel through a medium. It involves the transfer of energy from one point to another without the physical transfer of matter. Examples include sound waves traveling through air and electromagnetic waves traveling through space.
In a transverse wave, the direction of wave propagation is perpendicular to the direction of the wave oscillation.
In a longitudinal wave, the wavelength is the distance between two consecutive points that are in phase with each other. The propagation direction of the wave is the direction in which the wave is moving. The relationship between the wavelength and the propagation direction in a longitudinal wave is that the wavelength is parallel to the propagation direction.
In a transverse wave, the particles oscillate perpendicular to the direction of wave propagation. In a longitudinal wave, the particles oscillate parallel to the direction of wave propagation.
Well, it's often referred to as the direction of propagation of the wave.
Particles in a transverse wave vibrate perpendicular to the direction of the wave's propagation. In a longitudinal wave, particles vibrate parallel to the direction of the wave's propagation.