Radio Wave Length & Gravitational Force

In summary: Earth and its gravity strength are irrelevant.In summary, radio wavelengths are determined by the frequency of the electrical signal driving the antenna, and increasing the size of the antenna does not change the wavelength of the resulting electromagnetic wave. Gravity does not influence electromagnetic radiation, and different technologies are used to emit and detect different frequencies of electromagnetic radiation.
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Are the length of radio waves relative to the scale and gravitational force of origin?

In other words, if one increases, the scale of the Earth and total solar system by 10 times when this planet emits human produced radio waves, will the wavelength also be 10 times larger?
 
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Radio wavelengths are a property of the transmitter - the size of the Earth and its gravity strength are irrelevant.
 
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If you increase the size of the transmitter by 10, will the wavelength also increase by 10?
Gravitational force does not influence wavelength?
 
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If you increase the frequency of the electrical signal driving the antenna by a factor of 10, you will decrease the wavelength of the resulting EM wave by a factor of 1/10. Changing the size of the antenna does not change the wavelength of the resulting EM wave, it only changes the antenna's radiative efficiency.

And no, gravity is in no way related to electromagnetic radiation.

- Warren
 
  • #5
Thanks Warren
So if you increase the antenna by 10 it decrease the wavelength by 1/10.
As the size of the antenna goes up the wavelength goes down.
Is it the same in reverse?
I assume the answer is yes.
Are we able to translate all forms of radio wavelengths or are there some that we are not because we are restricted by size and cannot view?
 
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No, Entity, that's not at all what I just said. Please read my response again more carefully.

- Warren
 
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sorry I got you now
Are we able to translate all forms of radio wavelengths or are there some that we are not because we are restricted by size and cannot view?
 
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I have no idea what you mean by "translate." Do you mean, can we use antennas to send and receive all frequencies of electromagnetic radiation?

The answer is yes, if you define an "antenna" as any device intended to emit or detect electromagnetic radiation. Standard dipoles work well up to microwave frequencies, after which we need to use microwave horns and other exotic technologies. Above microwaves, up into the infrared and visible spectrum, another set of technologies come into play. Above ultraviolet, yet another, and so on. There is no single existing kind of "antenna" that can generate any arbitrary wavelength from radio to gamma rays, however.

The whip-like pieces of metal usually meant by the word "antenna" are only capable of emitting and detecting electromagnetic radiation over the part of the EM spectrum called "radio."

- Warren
 
  • #9
Thanks For your time I understand
 

1. What is the relationship between radio wave length and gravitational force?

The relationship between radio wave length and gravitational force is that they are both forms of energy. Radio waves are a type of electromagnetic radiation, while gravitational force is a fundamental force of nature. However, they do not directly affect each other.

2. How are radio waves and gravitational force measured?

Radio waves are measured in terms of frequency and wavelength, while gravitational force is measured in Newtons. Both can be measured using specialized equipment, such as radio telescopes for radio waves and gravitational wave detectors for gravitational force.

3. Can radio waves be affected by gravitational force?

No, radio waves are not affected by gravitational force. They travel through space at the speed of light and are not influenced by gravity. However, they can be affected by other forms of energy, such as obstacles or interference from other radio signals.

4. How does gravitational force impact objects in space?

Gravitational force is responsible for the motion and behavior of objects in space. It is the force that keeps planets in orbit around the sun and holds galaxies together. Gravitational force also plays a role in the formation of stars and the movement of celestial bodies.

5. Can gravitational force be used to transmit radio waves?

No, gravitational force cannot be used to transmit radio waves. Radio waves require a source of energy, such as an antenna or transmitter, to be produced and transmitted. Gravitational force does not have the ability to create or transmit electromagnetic radiation.

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