Radio Waves In the modern society, radio is the most widely used medium of broadcasting and electronic communication: it plays a major role in many areas such as public safety, industrial manufacturing, processing, agriculture, transportation, entertainment, national defense, space travel, overseas communication, news reporting and weather forecasting. In radio broadcasts, they use the radio waves which can be both microwaves and longer radio waves. These are transmitted in two ways: amplitude modulation (AM) and frequency modulation (FM).
These two kinds of wave have many differences. Radio waves are among the many types of electromagnetic waves that travel within the electromagnetic spectrum. Radio waves can be defined by their frequency (in hertz, after Heinrich Hertz, who first produced radio waves electronically), which is number of times they pass through a complete cycle per second; or by their wavelength, which is determined by the distance (by meters) that is traveled from the crest of one wave to the crest of the next.
Radio frequencies are measured in units called kilohertz, megahertz, and gigahertz. (1 kilohertz = 1000 hertz: 1 megahertz = 106 hertz, 1 gigahertz = 109 hertz).
All radio waves fall within a frequency range of 3 kilohertz, or 3000 cycles per second to 30 gigahertz. Within the range of frequencies, radio waves are further divided into two groups or bands such as very low frequency (VLF 10-30 k Hz), low frequency (LF 30-300 KHz), medium frequency (MF 300-3000 KHz), high frequency (HF 3-30 MHZ) and very high frequency (VHF 30-300 MHZ).
The Essay on Radio Waves Frequency Wave Audio
Radio waves travel at 186, 000 miles per second through air. In contrast, sound waves travel at only 1/5 of a mile per second. If a modulation is made of the radio wave that exactly reproduces the amplitude and frequency characteristics of the original sound wave, then sound can be transmitted rapidly over long distances. This leads to a very interesting phenomena. During a live broadcast in New ...
Amplitude modulation is the oldest method of transmitting voice and music through the airwaves is by amplitude modulation. This is accomplished by combining a sound wave from a microphone, tape, record, or CD with a ‘carrier ” radio wave.
The result: a wave that transmits voice or programming as its amplitude (intensity) increases and decreases. Amplitude modulation is used by station broadcasting in the AM band and by most international short wave stations. Frequency modulation is another way to convey information, voice, and music on a radio wave is to slightly change, or modulate, the frequency. The main advantage of FM broadcasting is of it is static free. But the drawback to FM is since the frequency is varied, station takes up more room on the band. Frequency modulation is, of course, used on the FM band.
And it is used for ” action band’ and ham transmission in the VHF/UHF frequency range. In amplitude modulation, what is modified is the amplitude of a carrier wave on one specific frequency. The antenna sends out two kinds of Am waves: ground waves and sky waves. Ground waves spread out horizontally from the antenna. They travel through the air along the earth’s surface. Sky waves spread up into the sky.
When they reach the layer of atmosphere called the ionosphere, they may be reflected back to earth. This reflection enables AM radio waves to be received at great distances from the antenna. Frequency modulation station generally reach audiences from 15 to 65 miles (24-105 km) away. Because of frequency of the carrier wave is modulated, rather than amplitude, background noise is reduced. In FM transmission, the frequency of the carrier wave varies according to the strength of the audio signal or program.
The Term Paper on Radio Waves And Electromagnetic Fields
•When you go to the simulation you will have a choice to either run the simulation or download the simulation. Run may not work on all computers. If it does not run, download the simulation and work from there. •When the simulation opens, play with the controls and buttons to become familiar with how the simulation works. •Note: A formal lab report is not required for this activity. You may cut ...
Unlike AM, where the strength of the carrier wave varies, the strength of the carrier wave in FM remains the same, while its frequency varies above or below a central value broadcast. FM transmission have a broadcast waves (88-108 MHZ) are shorter than AM broadcast waves (540 – 1600 k Hz) and do not go as far. In AM transmission, the amplitude of the carrier waves varies to match changes in the electromagnetic waves coming from the radio studio. In FM transmission, the amplitude of the carrier waves remains constant. However, the frequency of the waves changes to match the electromagnetic waves sent from the studio. Two types of radio waves are broadcast by AM transmitter: ground waves, which spread out horizontally from the ground and travel along the earth’s surface, and air waves, which travel up into the ionosphere, allows AM transmission to travel great distances.
AM radio stations with powerful transmitters can reach listeners as far as 1000 miles (1600 km) away. FM radio waves also travel horizontally and skyward. However, due to the higher frequency of the carrier waves, the waves that go skyward are not reflected. They pass through the atmosphere and into space. Although AM waves can be received at greater distances than FM waves, FM. waves do have advantages.
They are not affected by static as much as Am waves. Static is caused by electricity in the atmosphere. FM waves also result in a truer reproduction of sound than AM waves. Furthermore, FM has much better sound than AM because AM has different frequency and wavelength than FM. AM stations broadcast on frequencies of between 535 and 1605 kilohertz. The FM band extends from 88 to 108 megahertz.
So that people can compare two different bands on the radio.