-----Supposedly if you had a fluctuating high voltage(static) field that was the lowest amperage possible to carry a signal , there is 0.00 attenuation for that signal(almost like superfluidity of gases at extremely low temperatures).
-----The reasoning behind this thinking and what Nicola Tesla realized is that high voltage power lines have a lot less friction and can travel in thinner wires as well, due to their high voltage. And also at higher voltages, regular insulators become conductors due to ionization (like the way air conducts electricity in a lightning bolt). So what if you had a high enough voltage that you could pass a signal through any material in all directions and the only thing that could detect it was a metal receiver tuned to that frequency? Then you would have a long distance low wattage communications device with almost no "path loss".
-----Also, hypothetically, if you could take advantage of interference patterns of 2 coherent signals and control the interference patterns to propagate outwards in 1 direction (like a step up frequency instead of a step up power transformer, if this is even possible of course) and then stepped down the frequency at the receiver and translate the signal then you may have infinite channel possibilities and also the signal has traveled across a large distance, at the normal speed of light, but you wouldn't have had any signal loss or resistance along the way and it may use the same power as a regular cell phone, and had infinite channels. And because of the 0.00 signal loss you may not need to have actual base stations to boost the signal to a satellite or maybe you wouldn't even need as much energy as modern cell phones need to transmit a signal to a base station because they would go infinite distance on the very first weak signal and have no resistance along the way -
----- But realistically you would eventually have the same signal loss as stars have over long distances of their light's propagation. Which is what we see visually as a smaller star, when actually it's just extremely far away. And also if there was ever a metal object blocking the signal you wouldn't be able to receive it. And the only way to solve that is to not have metal structures all around your cities. Which I don't see humans doing any time soon.
-----And practically, the best way to utilize this device is to just transmit the signal to a satellite if you want to talk to someone that is far away on the planet. The reason being that the planet's surface is curved and you can't transmit through it's the planet's metal content, or even through a mountain.
-----To power the device it may be possible to have the energy from talking into the device be enough to send a signal to another receiver, and picked up at the same intensity as if they were standing right there talking to you (but only if there actually is no resistance, as in the theory).
----- So simplified it's a high voltage /"interference pattern utilizing" infinite frequency/ low wattage using/ virtually no resistance- communicator device
-----(Later added)------I was recently thinking about the communicator I heard about in the "Project Serpo" story and had the breakthrough thought that the wires that are thin and then get thick in the middle and then are thin again actually functions as a voltage boost as the amperage is spread out along the thick part of wire, each outward mm of thickness of the wire will have it's own portion of the original amperage. And in turn all of those outward mm sections of the wire will have the original voltage each, and in turn compound to form a higher voltage, or voltage increase.
-----And therefore the voltage will increase per mm thickness
-----Voltage= Wattage/Amperage/outward mm
- Wattage: Stays the same along thick part of wire ;
- Amperage: Is spread out along the thick part of the wire/outward mm ;
- Voltage: Then multiplies along the thick part of wire from compounding of each outward mm of thickness in the thick portion of the wire (each outward mm of the wire having only a portion of the original amperage of the thin portion of the wire) .[SEE PICTURE].
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