ALGORITHM OF TRUTH - SCALAR WAVES - TARGETED INDIVIDUALS - SCALAR WEAPONS - PDF - FULL INFO ARCHIVES
Vector illustration diagram with wavelengths, frequency and temperature.
These are the waves that do not need a material medium to propagate, unlike other types of waves, such as sound. James Clerk Maxwell, the Scottish physicist, was the first to make the theoretical observation that a variable electromagnetic field admits a solution whose equation of motion corresponds to that of a wave, hence electromagnetic waves. This suggested that the electromagnetic field was capable of propagating in the form of waves, both in a material medium and in a vacuum.
In his theory of relativity, Albert Einstein came up with the theoretical solution that explains the constancy of the speed of light, which since the 17th General Conference on Weights and Measures in 1983 it was agreed to set 299,792,458 m / sec. However, usually it is said that it is 300,000 km/sec. These waves make up electromagnetic radiation; it is a combination of oscillating electric and magnetic fields, which propagate through space transporting energy from one place to another.
These are the waves that do not need a material medium to propagate, unlike other types of waves, such as sound. James Clerk Maxwell, the Scottish physicist, was the first to make the theoretical observation that a variable electromagnetic field admits a solution whose equation of motion corresponds to that of a wave, hence electromagnetic waves. This suggested that the electromagnetic field was capable of propagating in the form of waves, both in a material medium and in a vacuum.
In his theory of relativity, Albert Einstein came up with the theoretical solution that explains the constancy of the speed of light, which since the 17th General Conference on Weights and Measures in 1983 it was agreed to set 299,792,458 m / sec. However, usually it is said that it is 300,000 km/sec. These waves make up electromagnetic radiation; it is a combination of oscillating electric and magnetic fields, which propagate through space transporting energy from one place to another.
Wavelength: Distance between two ridges.
Amplitude: It is the maximum disturbance of the wavehalf the distance between the ridge and the valley.
Frequency: Number of times the wave repeats per unit of time. If Hertz is used, it is the number of times the wave repeats for each second.
There are also two other interesting facts:
Period: 1 / frequency. It is the inverse of the frequency.
Speed: the speed of the wave depends on the medium through which it propagates (where it travels).
Electromagnetic waves are three-dimensional (by their number of directions of propagation) and transversal. The main idea is that if electric charges are made to oscillate between the ends of an antenna, an electric field and a magnetic field are generated, interacting with each other. Electromagnetic waves are the result of the interaction of these two fields.
How Do We Differentiate Them?
Amplitude: It is the maximum disturbance of the wavehalf the distance between the ridge and the valley.
Frequency: Number of times the wave repeats per unit of time. If Hertz is used, it is the number of times the wave repeats for each second.
There are also two other interesting facts:
Period: 1 / frequency. It is the inverse of the frequency.
Speed: the speed of the wave depends on the medium through which it propagates (where it travels).
Electromagnetic waves are three-dimensional (by their number of directions of propagation) and transversal. The main idea is that if electric charges are made to oscillate between the ends of an antenna, an electric field and a magnetic field are generated, interacting with each other. Electromagnetic waves are the result of the interaction of these two fields.
How Do We Differentiate Them?