Here is how I understand how a noise bridge works. The noise bridge
works on what we call a wheat stone bridge. It is the same principal as
the old Simpson s f b meters with the pointer use to work. Picture a
diamond, 4 resistors. On the left and right of the diamond is the input
and output. For the moment, we assume all resistors are the same value.
Now the top and bottom of the diamond of these 4 resistors is where we're
measuring, the test points. If the resistors are all equal, there is no
voltage difference between these two points, top and bottom test points.
No voltage drop, no current flow. You have same voltage drop across each
of the 4 resisters . So let us say we apply 10 volts to left and right of
the diamond, what I called input. If we assume, just to make things easy
to figure, say each resistor is 1 ohm, we'd have one ohm plus one ohm on
top leg, 2 ohms, one ohm plus one ohm on bottom leg, again 2 ohms. We
have two two ohm resisters in parallel. Hope this all making sense. Now
if you think about it, across each resister there would be a 5 volt drop.
Across the two middle tie points, top and bottom, there is no voltage, no
current flow, and we call this balanced. This is how the old audible
meters from s f b worked. When you balanced the bridge, the tone was
nulled out. They replaced the meter circuit with a wheatstone bridge.
Now is we change some values and make the antenna, a 50 ohm antenna one of
the legs, we can make a noise bridge. The old palamars and , the first
one I had was Omega t as I recall, had a pot on it. It had input and
output connectors. Input went to your antenna, output was the receiver.
Now, go back to our diamond and replace the top left resister with the
antenna, and the bottom right with a pot. The way these worked is you
tuned for minimum noise. These bridges had a noise generator, very broad
band, although they wouldn't go hardly to six. This noise is applied to
the left and right input points of our bridge. The receiver is hooked to
the top and bottom test points. You turned on the bridge and tuned
across the band until you found a dip in the noise. Remember we replaced
one resister with the antenna and other with a variable pot. Once you
found the dip, say a 50 ohm match or say a 70 ohm, whatever. You then
tuned the pot for minimum noise fed to the receiver, which you may recall
is across the output of the bridge, top and bottom test points. When the
pot reaches its lowest point, its resistance matches the impedance of the
antenna at that frequency and if you read the pot, that is the impedance
as well as the resonant point. The bridge is again balanced. With the
old palamars, you had to turn the rf gain way back or turn off a g c if
you could so you could hear the dip oint as you tuned across.
I don't have mine yet, but here is how the vectronics works as best as I
understand. Same as above except it puts out a pulsing noise, so it easy
to hear. The leg where the pot was above is 50 ohms, the antenna or tuner
is the unknown. You turn on the noise bridge, and start adjusting the
tuner. When it is 50 ohms, the bridge is balanced and noise is minimum.
I'll report when I get mine. The main problem with the older bridges is
if you bumped the mike button or transmitted into them puffff!!!!, gone
forever. As I read it, the vectronics has built in protection if you
forget and leave it on, so you can leave it in line all the time. I had a
friend who use to say, I just asked you what time it was, not how to build
a watch. <Smile> But, you did ask how it worked. Hope this makes sense.
73
Butch
WA0VJR
Node 3148
Wallace, ks.
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