Okay, a try at posting a formula......
Working from the assumption that there are only resistors (or that the capacitors are negligable at the frequencies of interest) Otherwise, replace every R with the corresponding Z(f) and the same for en(f) and in(f).
A single opamp,
Rin+ from positive input to ground
Rf from output to negative input
Rin- from negative input to ground
en noise voltage in V/sqrt(Hz)
in noise current in A/sqrt(Hz)
k Boltzmann constant 1.38*10exp(-23) J/K
T absolute temp in K
B noise bandwidth
let Req be equal to the parallel value of Rin- and Rf
The total noise voltage:
E= sqrt{ [ sqr(en) + sqr(in*Rin+) + sqr(in*Req) + 4*k*T*(Rin+) + 4*k*T*Req ] * B}
And sqr(x)= x*x
You can use this as the noise is independent of the signal, so the result can be added by superposition. Rin+ can be the input resistance of your source in a non-inverting setup, or Rin- can be the sum of your source and one of your gain setting resistors etc...
Whats wrong with 1500uF? I would use 4700uF 😉
Good idea.
Working from the assumption that there are only resistors (or that the capacitors are negligable at the frequencies of interest) Otherwise, replace every R with the corresponding Z(f) and the same for en(f) and in(f).
A single opamp,
Rin+ from positive input to ground
Rf from output to negative input
Rin- from negative input to ground
en noise voltage in V/sqrt(Hz)
in noise current in A/sqrt(Hz)
k Boltzmann constant 1.38*10exp(-23) J/K
T absolute temp in K
B noise bandwidth
let Req be equal to the parallel value of Rin- and Rf
The total noise voltage:
E= sqrt{ [ sqr(en) + sqr(in*Rin+) + sqr(in*Req) + 4*k*T*(Rin+) + 4*k*T*Req ] * B}
And sqr(x)= x*x
You can use this as the noise is independent of the signal, so the result can be added by superposition. Rin+ can be the input resistance of your source in a non-inverting setup, or Rin- can be the sum of your source and one of your gain setting resistors etc...
Whats wrong with 1500uF? I would use 4700uF 😉
Good idea.