parallel and single winding inductance are (almost) equal in case of ideal (high) coupling, which is in fact the usual design of a SEPIC inductor.
I disagree.
No problem, but the the inductor physics doesn't care about. Perhaps, you have heard about the inductance of a coil being proportional to n², squared number of turns. This is due to the simple fact, that doubling the number of turns 1. doubles the magnetization B and 2. doubles the voltage induced by dB = µdH.
The previous discussion was about "series" inductance of coupled inductors, e.g in post #3, no referring to a particular circuit. The term is used e.g. in the Coilcraft Coupled Inductors datasheets. I agree, that there's no series connection of inductors in usual SEPIC configuration. This means there's neither factor four nor factor two of single windings inductance involved.
No, you're mistaken. L=Φ*N/I. You forgot turns in your equation.
Ok, I absolutely agree that the total inductance of series-connected winding will be proportional to the square of the number of turns. However, the topicstarter was interested in the inductance of each of the two magnetically-coupled windings. If the current flows in only one winding (the second open) - the magnetic flux is Ф=L*N*I. When current flows in both windings, the magnetic fluxes of the two windings are added: Ф'=2*L*N*I. Consequently, the equivalent inductance of one winding is equal to L'=2*L, where L - the inductance of a single winding with the other open.
In the said circuit, the two inductors are connected in parallel, not in series. Placing two individual inductors of 22 uH results in a total inductance of 11 uH, while for the coupled inductors (k near 1), the total (parallel) inductance is equal to the inductance measured at one winding. As a result, input dI/dt is doubled for the uncoupled inductors.