@SouravGhosh: the country tag is meaningless. I was a contractor in the US for 19 years and this is standard procedure. It's called "plumping up a resume'". I once seriously pissed off a sales-guy for telling the client my resume' was faked. Sales-guy was amazed when two days later I got the gig. Client said they figured I was the only one who was being honest. :-) I just recommend that if you're going out on a contracting interview you should read what the sales-guy has put on your resume' before you get to the interview, so you know what the story-du-jour is. — Bob Jarvis 4 mins ago

I don't think so. If $\rho^* = \rho^\dagger$, the density matrix $\rho$ is not a Hermitian matrice unless it's real symmetric. — KarryMa 2 mins ago

Thanks magic_man & SanchayanDutta!! — Jchu4 23 mins ago

what about taking the traces $\mathrm{Tr}(U\sigma_i)$ for the different Pauli matrices $\sigma_i$ to get the components of the matrix and then just applying $\arccos$ etc where necessary? (I'm asking in case you already considered that but it didn't suit you for some reason) — glS 3 mins ago

@glS I didn't think about that before. Anyway, the traces you mention don't really look "nice". Say $\mathrm{Tr}(U\sigma_1) = -e^{i\lambda}\sin(\frac{\theta}{2})+e^{i\phi}\sin(\frac{\theta}{2})$. There are more than one variable involved in each such trace; a simple arcsin/arccos wouldn't work...at least the way I'm seeing it. — Sanchayan Dutta 5 mins ago

I didn't think about that before. Anyway, the traces you mention don't really look "nice". Say $\mathrm{Tr}(U\sigma_1) = -e^{i\lambda}\sin(\frac{\theta}{2})+e^{i\phi}\sin(\frac{\theta}{2})$. There is more than one variable involved in each such trace; a simple arcsin/arccos wouldn't work...at least the way I'm seeing it. — Sanchayan Dutta 23 mins ago

could you add an explanation to the code snippets you attached (what is that code exactly, where is it from, what's your problem with it)? Same applies to the screenshot. The question isn't very clear as it stands now — glS 16 mins ago

Please elaborate — mike_dole_z3 17 mins ago

On the GitHub link and maybe added/filmed after you gave this answer, Ryan O'Donnell at Carnegie Mellon has a 25-part lecture series on quantum computation. He has done a great service by placing videos of his lecture on YouTube. — Mark S 17 mins ago

@SanchayanDutta which edge cases are you referring to? For the restrictions, you are right. I have not been able to place them yet, if I simply those equations in the solve function sympy returns an empty result. As I said, I am not really an expert on sympy, but I'll try to figure out something. — tigerjack89 9 secs ago

Nice! Note that there are some edge cases though. Like when $a$ lies outside the range of $\cos(\theta/2)$. Moreover, you'd have to place the restrictions $0\leq \theta \leq \pi$ and $0 \leq \phi <2\pi$. — Sanchayan Dutta 23 mins ago

Say, your code wouldn't work for 1/2[[1+i,1-i],[1-i,1+i]] i.e. the square root of NOT. — Sanchayan Dutta 21 mins ago

@SanchayanDutta well, I think this is a limitation of Qiskit. If I remember correctly, the square root of not is implemented by an $R_Z(\pi/2)$ sandwiched between two H gates. I don't know if they can implement it directly. — tigerjack89 1 min ago

Indeed...global phase. — Sanchayan Dutta 7 mins ago

@SanchayanDutta ok, now I got what you were trying to say, adding a global phase. Am I right? — tigerjack89 8 mins ago

Yep, my Mathematica solution solves this problem. Not sure which matrix you're talking about. — Sanchayan Dutta 8 mins ago

@SanchayanDutta but the matrix used is different from (the modern versions of) Qiskit. Can the previous mathematica answer solve this instance of the problem? — tigerjack89 18 mins ago

Not quite. There's a trivial solution for this... — Sanchayan Dutta 23 mins ago

In short, there's no general way to do this for arbitrary $a_i$. It's basically what the whole field of quantum algorithms is about. — Sanchayan Dutta 1 min ago

Typically "officer" means the top employee for that area. Seems rather silly, yet a lot more common these days. — Joe Strazzere 21 secs ago