Numerically calculating Berry curvature in >2-band 2D systems?

The standard method for numerically calculating the Berry curvature of a 2D condensed matter system is given by Fukui-Hatsugai-Suzuki in this paper.
They discretize $k$-space into a grid with tiny rectangles and calculate the Berry curvature on each rectangle using so-called overlap matrices $U_mu$ and difference methods for derivatives. However, their definition of $U_mu$ involves only eigenstates of the band in question (as in $U_mu=langle n(k) | n(k+mu)rangle$).

However, the general definition of Berry curvature (as from this popular reference) explicitly involves >1 bands in the expression (unlike $U_mu$). Berry curvature $Omega$ is also known as an interband quantity. So, my question is, why is it okay to still use an intraband $U_mu$ to calculate $Omega$ in multiband systems? How does $U_mu$ incorporate effects of other bands? Or, have I misunderstood the application of the numerical scheme in the first reference?
I know that the multiband formula for $Omega$ comes from inserting the identity $Sigma_p |pranglelangle p|=1$ to $Omega=nabla times A$ (the berry connection, which is intraband like $U_mu$).

I know that for 2-band systems, $Omega_m$ = $-Omega_n$ for energy bands $m,n$. However, will $U_mu$ be appropriate even when this symmetry is not present, as in >2-band systems?
So, I wanted how $U_mu$ incorporates other bands’ effects better, and confirm that it is valid for use in multiband systems (as the authors claim), but with the intraband $U_mu$ I gave above. Thanks.