You mean you want the RGBA color with maximum transparency which, when drawn on top of a white background, gives the original RGB color?

Let *R*_{0}, *G*_{0} and *B*_{0} be the components of the original color, each ranging from 0.0 to 1.0, and let *R*, *G*, *B* and *A* be the components of the new RGBA color (with *A* = 1 denoting 100% opacity). We know that the colors must satisfy:

*R*_{0} = *A*·*R* + (1 − *A*)

*G*_{0} = *A*·*G* + (1 − *A*)

*B*_{0} = *A*·*B* + (1 − *A*)

which, if we knew *A*, we could easily solve for *R*, *G* and *B*:

*R* = (*R*_{0} − 1 + *A*) / *A* = 1 − (1 − *R*_{0}) / *A*

*G* = (*G*_{0} − 1 + *A*) / *A* = 1 − (1 − *G*_{0}) / *A*

*B* = (*B*_{0} − 1 + *A*) / *A* = 1 − (1 − *B*_{0}) / *A*

Since we require that *R* ≥ 0, *G* ≥ 0 and *B* ≥ 0, it follows that 1 − *R*_{0} ≥ A, 1 − *G*_{0} ≥ A and 1 − *B*_{0} ≥ A, and therefore the smallest possible value for *A* is:

*A* = max( 1 − *R*_{0}, 1 − *G*_{0}, 1 − *B*_{0} ) = 1 − min( *R*_{0}, *G*_{0}, *B*_{0} )

Thus, the color we want is:

*A* = 1 − min( *R*_{0}, *G*_{0}, *B*_{0} )

*R* = 1 − (1 − *R*_{0}) / *A*

*G* = 1 − (1 − *G*_{0}) / *A*

*B* = 1 − (1 − *B*_{0}) / *A*

Ps. For a *black* background, the same formulas would be even simpler:

*A* = max( *R*_{0}, *G*_{0}, *B*_{0} )

*R* = *R*_{0} / *A*

*G* = *G*_{0} / *A*

*B* = *B*_{0} / *A*

Pps. Just to clarify, all the formulas above are for *non*-premultiplied RGBA colors. For premultiplied alpha, just multiply *R*, *G* and *B* as calculated above by *A*, giving:

*R* = *A* · ( 1 − (1 − *R*_{0}) / *A* ) = *R*_{0} − (1 − *A*)

*G* = *A* · ( 1 − (1 − *G*_{0}) / *A* ) = *G*_{0} − (1 − *A*)

*B* = *A* · ( 1 − (1 − *B*_{0}) / *A* ) = *B*_{0} − (1 − *A*)

(or, for a black background, simply *R* = *R*_{0}, *G* = *G*_{0} and *B* = *B*_{0}.)