How can that be? Another way of looking at it is that the networks we connect to have improved so dramatically, that they’ve been able to deal with phone designers screwing up the performance of the handset antenna without much backlash from consumers.
Antennas can be difficult to wrap our heads around because they're both electrical and mechanical. The basis of this (in my opinion) is that radio waves have physical size, and the size of the antenna has to match the size of the radio waves it's going to handle. That's a concept that most people simply don't have until they take a class to get a ham radio license, or start looking into building an antenna. Until that time, either they never saw the radio had an antenna (most AM/FM radios have an internal antenna the user never sees) or antenna was just a short piece of wire sticking out of the radio.
Every frequency of radio has a specific wavelength, and they always follow the relationship that frequency times wavelength is the speed of light, or c=f*l.
Now an antenna doesn't have to be a wavelength long; in fact they fit the antenna best when the antenna is one half wavelength long, fed at the center. This is going to blow some of your minds, but the current and voltage distribute like this on a half wave long, center-fed antenna, with each side 1/4 wave long. Let's call the voltage positive on the top side (left) and negative on the bottom (right); so current is positive above the line, too.
The "why??" is pretty simple. Remember that power is voltage time current, so if the power is constant, the product can stay the same while the current and voltage can both vary from zero to their maximum along the wires. The current is minimum at the ends because the current has nowhere to go. Electrons can't go past the end of the wire. The voltage is maximum at the ends because the current stops; since I*V is constant and I is getting very small, the voltage gets very big.
Note that the picture is a snapshot of a very short period in time. The voltage is continually changing polarity, end to end, at the frequency of the wave, and so is the current, but the current and voltage being out of phase with each other as pictured (one max while the other is min) doesn't change. There's a good animation in the wikipedia.
By the way: if you want to build a dipole, two quarter wave long wires fed in the middle, a century of experience says to cut the wire to 468/f, where f is the frequency in MHz and it gives you the answer in feet. Antennas interact a lot with their environment, so it's not uncommon to have to tweak those dimensions to get the best antenna, but this ordinarily gets you close enough to start.
Remember how I said that "the size of the antenna has to match the size of the radio waves it's going to handle"? There's some slack in that statement because as you move the frequency away, it can still "mostly fit". This is what's called the bandwidth of the antenna. This drawing shows the wave fitting on the antenna because the peak of current is a half wave. If the frequency gets too far away, the current would go below zero and every cycle would look a little different because the position of where it crosses zero would move around.
In reality, non-resonant antennas are used regularly. Just as Power is voltage times current and constant, let me drag a concept back from AC circuits: impedance. Impedance is an AC resistance which includes the effects of resistance and reactance. Just like DC resistance is defined as Voltage divided by Current (V/I), impedance is V/I with AC measures. Antennas have a defined impedance, like any AC circuit, and you can make an antenna's impedance look better with tuning circuits. Manual and automated tuners are commonplace. They allow you to make a non-resonant antenna more useful.
The half wave dipole is a standard antenna in a few senses. They are used as an element in other antennas, and their performance by themselves is a standard of comparison. The other standard antenna is 1/2 of a half wave dipole, a quarter wave monopole, usually called a quarter wave vertical because half the antenna is replaced with it's "reflection" in a mirror-like ground that it's mounted vertically over. The current and voltage waves look exactly like the half wave dipole.
In particular, cell phones went from having very obvious, external, quarter wave whip style antennas to internally mounted or otherwise hidden antennas, like these:
Tomorrow - deeper into the weeds.
In addition fractal geometry has allowed for internal antennas of significant length that still fit inside the body of the cell phone etc.
ReplyDeleteYou need to type slower, my eyes just glazed over trying to comprehend this.
ReplyDeleteI'm going to try reading it again.
It has math in it and that fooks me every time.
Sorry if it blurred your vision. I actually took a long time writing that.
DeleteIf I can help clear up anything, let me know.
Maybe I was expecting a more fundamental explanation, to me, this is more like antenna 102 instead of antenna 101.
DeleteI already understand the wave length part, amplitude, frequency and resonance. Plus the half wave and quarter wave parts. I just spent an hour on Youtube and found a couple that covered the basics pretty well so with a little more studying I will be up to speed with this. Since I have a cheapie CB radio on it's way to me and I already have an antenna, I am now learning about tuning antennas with the SWR unit.
I have also been on Ebay and Amazon hunting down an inexpensive unit because for me at this time, it will be a one time use item.
I appreciate you doing this and the time it took to get all this info gathered, organized and formatted. I'm just that one guy you always run into that has a hard time grasping theory out of thin air.