I just figured if we parallel n exact same resistors together,
we will get 1/n times the noise power of each resistor.
For example, we we want 1 ohm resistance, we can
parallel 2 pieces of the 2-ohm resistors and get the noise
power half of what we'd get had we used a 1 ohm resistor.
(Assuming 1-ohm and 2-ohm resistors generate equal noise
power).
Is this already well known besides the fact that n parallel
resistors would reduce the tolerance error by n times?
Any opinions?
-Sean
we will get 1/n times the noise power of each resistor.
For example, we we want 1 ohm resistance, we can
parallel 2 pieces of the 2-ohm resistors and get the noise
power half of what we'd get had we used a 1 ohm resistor.
(Assuming 1-ohm and 2-ohm resistors generate equal noise
power).
Is this already well known besides the fact that n parallel
resistors would reduce the tolerance error by n times?
Any opinions?
-Sean
Resistor voltage noise En=2*SQRT(k * T * B * R),
k = Bolzman constant
T = temperature
B = bandwidth of interest
R = resistance in ohms
Depending on material you also have other noise sources, usually proportional to current.
Paralleling n resistors does not reduce noise or tolerance by a factor of n, but by a factor of SQRT
because the noise in n resistors is not correlated.
If you use that fact and include it in the equation above, you will see that n parallel resistors of X ohms generate exactly the same noise voltage as a resistor of X/n ohms.
I would say you have assumed a bit too much about your facts
k = Bolzman constant
T = temperature
B = bandwidth of interest
R = resistance in ohms
Depending on material you also have other noise sources, usually proportional to current.
Paralleling n resistors does not reduce noise or tolerance by a factor of n, but by a factor of SQRT
because the noise in n resistors is not correlated.If you use that fact and include it in the equation above, you will see that n parallel resistors of X ohms generate exactly the same noise voltage as a resistor of X/n ohms.
I would say you have assumed a bit too much about your facts
Yes, lower resistence means lower noise, whether you use a single resistor or paralleled bunch. But there is some dependency on the type of resistor you use. Wirewound resistors are quieter than the other types.
Take a look here:
http://www.aikenamps.com/ResistorNoise.htm
To reduce thermal noise, you could try cooling down the circuit with a peltier block or something. But practically, you may have to cool down to liquid nitrogen temperatures to get significant reduction in noise.
John.
Take a look here:
http://www.aikenamps.com/ResistorNoise.htm
To reduce thermal noise, you could try cooling down the circuit with a peltier block or something. But practically, you may have to cool down to liquid nitrogen temperatures to get significant reduction in noise.
John.
Your opinions are much appreciated. I was wrong I see now that my assumption that the noise power was independent of the resistance is way too much. I agree with ilimzn:
Yes, the "average" noise power generated by paralleling n resistors will be the same (not larger, not smaller) as using only one resister. (The average noise power is found using the autocorrelation of the voltage across the resistor, assuming the voltages across the resistors are uncorrelated and have zero mean).
-Sean
I see now that my assumption that the noise power was independent of the resistance is way too much. I agree with ilimzn:Yes, the "average" noise power generated by paralleling n resistors will be the same (not larger, not smaller) as using only one resister. (The average noise power is found using the autocorrelation of the voltage across the resistor, assuming the voltages across the resistors are uncorrelated and have zero mean).
-Sean
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