Thursday, November 28, 2019
The Physics Of Sound Essays - Acoustics, Waves, Sound,
The Physics Of Sound Sound surrounds us at all times. The ring of an alarm clock or the whistle of birds may wake us up in the morning. Through out the day, we hear a variety of sounds; for instance, the banging of pots and pans, the roar of traffic, and the voices of people. When we fall asleep at night, we might listen to the sounds of frogs croaking or the wind whistling. All sounds have one thing in common. This being that the vibrations of an object makes every sound. When an object vibrates, it causes the air around it to vibrate. The vibrations in the air travel out from all directions of the object. They then reach our ears, and the brain reads them as sounds. Many sounds we hear travel through the air; however, they can also travel through solid objects like the earth. Our voice is made in the larynx, which is a part of the throat. Two small pieces of tissue are spread across the larynx. These pieces, called vocal chords, make the opening smaller. Air from he lungs quickly passes trough the tightened chords, causing them to vibrate. The vibrations make the sound of the voice. The tighter the chords are, the faster the vibrations and the higher the resulting sound. If a rock is thrown onto a still pond, several waves travel out from the place where the rock hit the surface. Likewise, sound moves in waves through the air or some other medium. The understanding that sound travels in the form of waves may have originated with the artist Leonardo Da Vinci in 1500. Generally, waves can be spread transversely or longitudinally. In both cases, only the energy of wave motion is spread through medium. No portion of the medium actually moves very far. As the waves caused by the moving object travel outward, they are carried by a medium. This movement causes compression. As the movements move backward it is called rarefractions. Sound requires a medium to travel; therefore, it cannot travel in space, which is a vacuum with no medium. The number of compressions and rarefractions per second is called frequency, The more rapidly and object vibrates, the higher the frequency. Frequency is measured in hertz. As the frequency of a sound wave increases, the wavelength decreases. Wavelength is the distance between one point on a wave to the corresponding point on the next wave. Most people hear sounds with frequencies that fall between 20 and 20,000 hertz. Many animals can hear sounds about 20,000 hertz. A person's voice can have a range of about 85 to 1,100 hertz. When sound waves leave one medium and enter another in which the speed of sound differs, the direction of the waves is altered. This change in direction results from a change in the speed of waves called refraction. Sound waves can also be refracted if the speed of the sound changes according to their position in a medium. The waves bend toward the region of slower speed. Sound travels farther when the air is cooler. During the day, the ground is warmer than the air above. Sound waves are bent away from the ground into the cooler air above, where their speed is slower allowing the sound to be heard over longer distances. The spreading out of waves as they pass by the edge of an obstacle or through and opening is called diffraction. It occurs whenever a sound wave encounters an obstacle or opening. Diffraction enables sound to be heard around a corner, even though no straight path exists from the source of the sound to the ear. If sound travels at about the same speed in both materials with the same density, little sound will be reflected. Instead, most of the sound will be transmitted into the new medium. If the speed differs greatly in the two mediums and their densities are greatly different, most of the sound will be reflected. The intensity of a sound is related to the amount of energy in the sound waves. Intensity depends on the amplitude of the vibrations making the waves. Amplitude is the distance that the object producing the sound travels as it vibrates.