For those wondering where those magical formulas from the other answers come from, here's a derivation following this example.

Starting with the transfer function for the Butterworth filter

`G(s) = wc^2 / (s^2 + s*sqrt(2)*wc + wc^2)`

where `wc`

is the cutoff frequency, apply the bilinear z-transform, i.e. substitute `s = 2/T*(1-z^-1)/(1+z^-1)`

:

`G(z) = wc^2 / ((2/T*(1-z^-1)/(1+z^-1))^2 + (2/T*(1-z^-1)/(1+z^-1))*sqrt(2)*wc + wc^2)`

`T`

is the sampling period [s].

The cutoff frequency needs to be pre-warped to compensate for the nonlinear
relation between analog and digital frequency introduced by the z-transform:

`wc = 2/T * tan(wd*T/2)`

where `wd`

is the *desired* cutoff frequency [rad/s].

Let `C = tan(wd*T/2)`

, for convenience, so that `wc = 2/T*C`

.

Substituting this into the equation, the `2/T`

factors drop out:

`G(z) = C^2 / ((1-z^-1)/(1+z^-1))^2 + (1-z^-1)/(1+z^-1)*sqrt(2)*C + C^2)`

Multiply the numerator and denominator by `(1+z^-1)^2`

and expand, which yields:

`G(z) = C^2*(1 + 2*z^-1 + z^-2) / (1 + sqrt(2)*C + C^2 + 2*(C^2-1)*z^-1 + (1-sqrt(2)*C+C^2)*z^-2')`

Now, divide both numerator and denominator by the constant term from the denominator. For convenience, let `D = 1 + sqrt(2)*C + C^2`

:

`G(z) = C^2/D*(1 + 2*z^-1 + z^-2) / (1 + 2*(C^2-1)/D*z^-1 + (1-sqrt(2)*C+C^2)/D*z^-2')`

This form is equivalent to the one we are looking for:

`G(z) = (b0 + b1*z^-1 + b2*z^-1) / (1 + a1*z^-1 +a2*z^-2)`

So we get the coefficients by equating them:

`a0 = 1`

`a1 = 2*(C^2-1)/D`

`a2 = (1-sqrt(2)*C+C^2)/D`

`b0 = C^2/D`

`b1 = 2*b0`

`b2 = b0`

where, again, `D = 1 + sqrt(2)*C + C^2`

, `C = tan(wd*T/2)`

, `wd`

is the desired cutoff frequency [rad/s], `T`

is the sampling period [s].