![]() ![]() The animation above shows the propagation of a spherical wave pulse in a medium where the wave speed in the x-direction is constant, but where the speed in the vertical y-direction decreases with height ![]() The sound waves are being refracted upwards and will never reach the observer. A person standing in the shadow zone will not hear the sound even though he/she might be able to see the source. This can create a "shadow zone" region into which the sound wave cannot penetrate. As a result, the wave changes direction and bends upwards. This means that for a sound wave traveling close to the ground, the part of the wave closest to the ground is traveling the fastest, and the part of the wave farthest above the ground is traveling the slowest. Since the temperature decreases with height, the speed of sound also decreases with height. For example, during the day the air is warmest right next to the ground and grows cooler above the ground. Often the change in the wave speed, and the resulting refraction, is due to a change in the local temperature of the air. The speed of a sound wave in air depends on the temperature (c=331 + 0.6 T) where T is the temperature in oC. Instead the wave speed changes gradually over a given distance. In acoustics, however, sound waves usually don't encounter an abrupt change in medium properties. Since the wave speed is the same everywhere, there is no refraction, and the wave does not change direction as it propagates. The wave expands outwards as an ever expanding circle, with the wave traveling at the same speed in all directions. In the above animation a spherical wave pulse propagates in a medium where the wave speed is constant in all directions. Notice that as the wavefronts cross the boundary the wavelength changes, but the frequency remains constant. Snell's law relates the directions of the wave before and after it crosses the boundary between the two media. Most often refraction is encountered in a study of optics, with a ray of light incident upon a boundary between two media (air and glass, or air and water, or glass and water). When a wave encounters different medium where the wave speed is different, the wave will change directions. The speed of a wave depends on the elastic and inertia properties of the medium through which it travels. This phenomena is due to the refraction of sound waves. At night, however, you can not only see the campers on the other side of the lake but you can also hear their conversations as they sit around their camp fire. During the day you can see campers on the other side of the lake, but you cannot hear them. Suppose you are camping on the shore of a lake which is not too wide, maybe 1/2 a mile across or so. RussellĪnd may not used in other web pages or reports without permission. Understanding the behaviours of sound waves, including reflection, refraction, and diffraction, is important in many fields, including acoustics, engineering, and communication.All text and images on this page are ©2004-2011 by Daniel A. Diffraction of sound waves is important in many applications, such as in the design of concert halls and in the study of the effects of obstacles on sound propagation. The degree to which a sound wave diffracts depends on the wavelength of the sound wave and the size of the obstacle. When a sound wave encounters an obstacle, it may bend around the edges of the obstacle and spread out into the region behind it. Refraction of sound waves is important in many applications, such as in the design of lenses and in the study of atmospheric acoustics. The degree to which the sound wave bends depends on the difference in the speed of sound between the two mediums, as well as the angle at which the sound wave enters the new medium. When a sound wave passes from one medium to another, its speed and direction can change. Reflection of sound waves is important in many practical applications, such as echolocation and soundproofing. The angle at which the sound wave hits the surface (the angle of incidence) and the angle at which it reflects (the angle of reflection) obey the law of reflection, which states that the angle of incidence is equal to the angle of reflection. This is known as reflection and is what is normally heard as an echo. When a sound wave encounters a surface, some of the sounds may bounce back in the opposite direction. These behaviours include reflection, refraction, and diffraction. Sound waves can exhibit several different behaviours as they travel through different mediums or encounter obstacles. ![]()
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