Is Japan witnessing the death of AM radio? Since February, some commercial radio broadcasters have begun a trial suspension of AM radio, with a real possibility the pause will extend to a permanent discontinuation across the country as broadcasters look to cut costs. Thirteen of the 47 commercial operators in…
Buildings won’t perfectly absorb signals but it will attenuate the signals that pass through them.
The gaps In a faraday cage determine the maximum wavelength of the electromagnetic signal that can pass through. AM signals have very long wavelengths, and are more likely to get distorted
Any metal in a building will act to distort and absorb signals, the more metal, like rebar in concrete, the less signal can get through.
Examples:
Consider the ocean, ionic water, very difficult to get radio signals because there are so many dense charge carriers to absorb the radio waves.
Consider the earth: sending radio signals through the center of the earth is difficult because of all the metal, electron carriers in the earth itself.
Consider wifi in a modern concrete and rebar office building, one or two rooms over and the signal gets absorbed quite effectively.
I think I understand better where you’re coming from. I have a variety of homemade low frequency antennas, typically on the order of 20 meter wavelength, and I observe lower frequencies clearly get better reception inside buildings. Transmission tends to be more variable because I have an increasingly large near field zone that’s effectively impossible to clear. Indeed, my real world experience has always been the opposite. Lower frequencies appear to get through better, provided you can actually talk out. I usually prefer to modulate the H field because it’s orthogonal to household noise sources and after some distance away doesn’t couple to metal.
I’m not sure why this is. Perhaps buildings are different enough from Faraday cages? Lower frequencies diffract and bend around objects much much more effectively than high frequencies.
I have some RF design engineer friends and I’ll ask them why my experience is different.
Buildings won’t perfectly absorb signals but it will attenuate the signals that pass through them.
The gaps In a faraday cage determine the maximum wavelength of the electromagnetic signal that can pass through. AM signals have very long wavelengths, and are more likely to get distorted
Any metal in a building will act to distort and absorb signals, the more metal, like rebar in concrete, the less signal can get through.
Examples:
Consider the ocean, ionic water, very difficult to get radio signals because there are so many dense charge carriers to absorb the radio waves.
Consider the earth: sending radio signals through the center of the earth is difficult because of all the metal, electron carriers in the earth itself.
Consider wifi in a modern concrete and rebar office building, one or two rooms over and the signal gets absorbed quite effectively.
I think I understand better where you’re coming from. I have a variety of homemade low frequency antennas, typically on the order of 20 meter wavelength, and I observe lower frequencies clearly get better reception inside buildings. Transmission tends to be more variable because I have an increasingly large near field zone that’s effectively impossible to clear. Indeed, my real world experience has always been the opposite. Lower frequencies appear to get through better, provided you can actually talk out. I usually prefer to modulate the H field because it’s orthogonal to household noise sources and after some distance away doesn’t couple to metal.
I’m not sure why this is. Perhaps buildings are different enough from Faraday cages? Lower frequencies diffract and bend around objects much much more effectively than high frequencies.
I have some RF design engineer friends and I’ll ask them why my experience is different.