I'm relatively new to the topic but I'm intending to transmit some data from a measurement system in a cave to a receiver on the surface. I understand that I can use a SDR (software defined radio) to receive radio signals on the surface but from all of the tutorials and material I've come across online I can't seem to find a way to to transmit data at frequencies around 80 kHz to the surface. I've chosen 80 kHz because frequencies such as 88 – 108 MHz would encounter far too much attenuation whilst attempting to penetrate the ground and frequencies around 80 kHz are used by commercial cave radios that utilise voice links. However, I'm not interested in transmitting voice links but rather simple files. I've been told that using VCO circuits to simply generate a low frequency signal and modulate it with an input signal would be unstable and unreliable so my understanding of FM radio has proved useless at this point.
I suppose my question is what is the best method for transmitting signals at these low frequencies to the surface? How do I even begin to consider the design of a system that does this? I'm still a beginner with RF engineering so any help would be valuable.
Edit: I'd like to make it clear that I'm not aiming for "line of sight" transmission through air but instead "through the earth" (TTE) transmission through a conductive ground medium. Limestone, to be exact.
Best Answer
There's no evidence to suggest that what you say is true.
I'd consider this as a good basis for a decent VCO at 80 kHz: -
Picture from this site. Or consider the LM567 from the same site: -
Then you'll need a tuned coil driver to implement magnetic field comms as you imply.
It's a magnetic field transmitter so, make your coil as big as you can and use decent capacitors to parallel tune it. The Q of your tuned circuit can be higher if your data rate is lower but, if I were designing it, I would not hesitate to model it all in a simulator tool.
Rather than call it FM, call it FSK - it stands for frequency shift keying and can use exactly the same circuits shown above.
You also have to bear in mind that this type of transmission and reception uses the magnetic part of an electromagnetic wave. This is because the electric field part will not penetrate very far through the strata due to mineralized water for one thing. Additionally, because the frequency is low, the "antenna" is very short for the wavelength used and, it would be useless at transmitting any serious E-field any way.
So, it uses a magnetic field and, as you move away from the "antenna" (basically a large diameter coil of wire), the magnetic field falls with distance cubed. Compare this with a regular RF system that can utilize both E and H-fields; those fields fall linearly with distance. This is the magical thing about proper radio - in open fields (for example), for the same power to the "antenna", proper RF goes waaaaaaaaaay further than E or H-fields on their own. Bear this in mind.