Many quantum algorithms, including Shor's celebrated factoring and discrete log algorithms, proceed by reduction to a hidden subgroup problem, in which a unknown subgroup $H$ of a group $G$ must be determined from a quantum state $\psi$ over $G$ that is uniformly supported on a left coset of $H$. These hidden subgroup problems are typically solved by Fourier sampling: the quantum Fourier transform of $\psi$ is computed and measured. When the underlying group is nonabelian, two important variants of the Fourier sampling paradigm have been identified: the weak standard method, where only representation names are measured, and the strong standard method, where full measurement (i.e., the row and column of the representation as well as its name) occurs. It has remained open whether the strong %standard method is indeed stronger, that is, whether there are hidden subgroups that can be reconstructed via the strong method but not by the weak, or any other known, method.
In this article, we settle this question in the affirmative. We show that hidden subgroups of semidirect products of the form $\Z_q \ltimes \Z_p$, where $q \mid (p-1)$ and $q = p/ \polylog(p)$, can be efficiently determined by the strong standard method. Furthermore, the weak standard method and the ``forgetful'' abelian method are insufficient for these groups so that, in fact, it appears that use of the corresponding nonabelian representation theory is crucial. We extend this to an information-theoretic solution for the hidden subgroup problem over the groups $\Z_q \ltimes \Z_p$ where $q \mid (p-1)$ and, in particular, the affine groups $A_p$. Finally, we prove a simple closure property for the class of groups over which the hidden subgroup problem can be solved efficiently.