Not all considerations are intuitively obvious. Nor are they brought out in tutorials.
Of course we have the standard formula for center frequency (which is independent of resistance).
There is the Q factor, which is associated with bandwidth. (This depends on resistance.)
And it makes a difference whether the LC is series, or parallel (tank). Then for either configuration, we can tap at one end to obtain a bandpass, or at the other end to obtain a notch.
There are the parallelogram shapes, created when we calculate effective impedance for coils and capacitors, for given frequency and resistance.
I believe simulations are invaluable for giving further insights.
Example:
1.
This simulation shows how Q factor (and thus bandwidth) is affected by input resistance. (This input resistance might be known or unknown.)
Five identical LC tanks. Input resistors increase in steps of 10X. A sine sweep is applied.
2.
This simulation illustrates various Q factors (and thus bandwidths), based on the ratio of coil value to capacitor value. (This is despite the fact that the combinations have identical center frequency).
Four series LC filters, with identical series resistance.
Coils decrease by steps of 10X. Caps increase by steps of 10X.
A sine sweep is applied.