the word "cannot" in knowledge, is incorrect, the correct word is "don't know", because there is no impossible, but we just don't know how to do it now, may be we know how, later. — remon78eg 15 mins ago

if you're implementing using QISKit the video shows the code also. — Aman 13 mins ago

@remon78eg The qualifier that applies throughout this site is "within the standard theory of Quantum Mechanics". True, it might be a physically permissable operation, but one would have to go beyond standard quantum mechanics to achieve it. — DaftWullie 20 mins ago

Hi, could you share the code you are running when you get this error? — met927 17 mins ago

(Hint: does being an eigenstate of $\pm i Y$ characterise a unique single-qubit state?) — Niel de Beaudrap 14 mins ago

Just to clarify, are you trying to import cplex within the Jupyter Notebook in IBM Q Experience? — Matthew Stypulkoski 15 mins ago

We're just talking about a group. There are well defined groups whether they be matrix groups or in a projective quotient. There are well defined group actions whether they be linear or merely algebraic. — AHusain 11 mins ago

Travelling last night. Anyway. The action of PU(n) descends to an action on $CP^{n-1}$. In this case, the equivalence class of $(\alpha,\beta)$ goes to that of $(\beta,-\alpha)$. So $(\alpha,\beta) \equiv (\beta,-\alpha)$ is the condition for fixed points of group action. This translates into $(1,\frac{\beta}{\alpha})=(1,\frac{-\alpha}{\beta})$. Which becomes $\alpha^2=-\beta^2$. A homogeneous equation so cuts out a well defined locus in projective space. $\alpha = \pm i \beta$. Rescale solutions and you get two equivalence classes $(1,\pm i)$. I never claimed anything about unique solutions. — AHusain 13 mins ago

@AHusain: that's all well and good. It also doesn't matter for my question, which is about unique solutions. The ability to specify individual states is lost if you pass to equivalence classes of matrices. I am indicating that this is a relevant application, which requires matrices rather than equivalence classes of them, and which motivates having the Hermitian matrix $Y$ in particular. (Deleted and revised for improved concision and clarity) — Niel de Beaudrap 11 mins ago

As for today, only the introduction is free. But the remaining content is very promising. — Ezeq 22 mins ago