thats super cool thanks for the help! I'm ready for the photon phuture, ill start in on the docs rn — Aidan Collins 11 mins ago

Amazing! and thanks for this thoughtful response. In the first step, how are the f(1sub2) just flipped into f(0sub2)? I think this is where im missing some understanding. — VP9 19 secs ago

thank you! wish i could accept it twice :) — VP9 58 secs ago

That's because they are equal (f(0) = f(1)). In the other case the not-f(1) will change into f(0) — Mariia Mykhailova 15 mins ago

Happy to help :-) — Mariia Mykhailova 7 mins ago

I edited the notation as you point out, thank you very much. What I want is to permute bit in the quantum state, so I wonder if classical mean also works on my case. Since the state is in a superposition of every possible bit too, bit flip on one qubit will affect every bit in the state. — Poramet Pathumsoot 43 secs ago

By the way, are you assuming that you know the coefficients a or not? (I assumed not. I guess the other answer assumes that you do) — DaftWullie 16 mins ago

The circuit construction is the same in classical as quantum. You just have to replace the classical circuit elements with the same thing but one that is capable of operating on super positions. The bit flip exam0le that you give, for instance, is both a classical and a quantum operation. But the theory of the circuit construction is easier to understand from the classical perspective. — DaftWullie 18 mins ago

Have you checked which Y quirk is using? It’s a standard gate and you’ve specified a (different) custom gate with the same name. — DaftWullie 3 mins ago

I know quirk uses the opposite convention, but you’ll almost universally find elsewhere that the top qubit in a circuit diagram corresponds to the first qubit in the tensor product. It’s probably worth being explicit about your convention especially when you’re asking people to hunt for faults. Not that it helps solve your problem.... — DaftWullie 5 mins ago

Hi and welcome to Quantum Computing SE. Could you please provide a link to a paper you refer to? — Martin Vesely 22 mins ago

I know the coefficient a, but instead of modified wave amplitude itself which may involve many controlled rotation gates, I prefer a bit modification approach. — Poramet Pathumsoot 23 mins ago

Note that $\theta = 2\arccos(\sqrt{2/3})$... — draks ... 1 min ago

What I was asking is whether you have carefully checked that the output of quirk is consistent with the gate you think it’s using? — DaftWullie 6 mins ago

@DaftWullie, Question has been edited as suggested. Also I've used custom Y gate and not Pauli-Y. — Omkar 15 mins ago

Thank you @Craig Gidney. Note the last entry of $H_{YZ}$ is $\frac{-1}{\sqrt{2}}$ — Omkar 20 mins ago

As Craig Gidney mentioned in the answer, there was a confusion in order in which I've applied the gates. Now I've corrected it. Thank you @DaftWullie — Omkar 23 mins ago

Thanks a lot @DaftWullie, it makes sense. Could you please explain to me why all terms commute ? I was trying to answer it myself as the paper contains no notion of order, so I deduced it must commute but I'm unsure why. I found this property over matrix exponential, saying that if X and Y commutes then $e^X$ and $e^Y$ also commutes. $\sigma^x$ and $\sigma^x$ commutes , and multiplying them with a scalar (here $-i \beta$) preserves commutation, but what about $\sigma_j^x$ and, let's say, $\sigma_{j+1}^x$ ? — nathan raynal 20 mins ago

Well, the easiest way to think about it in this specific case is that each term acts on different qubits. If I do a unitary on qubit $j$ followed by a unitary on qubit $j+1$, that should be the same as a unitary on qubit $j+1$ followed by a unitary on qubit $j$. Those two qubits could be light years apart (where time ordering of events might not even make sense)! — DaftWullie 20 mins ago

Ok, this is cool as independently I got more or less the same solution, although it took me much longer than you :-) — sycramore 8 mins ago

@Omkar Thanks, fixed. — Craig Gidney 17 mins ago

Check this resource out edx.org/course/quantum-machine-learning and the notebooks here github.com/vishwesh5/Quantum-Machine-Learning — Sam Palmer 3 mins ago

@CraigGidney yes, of course, but do you think that's what they mean by "at most $O(L^2)$ operations"? Why would they write $O(L^2)$ when you can write $O(L)$? — MBolin 8 mins ago

The complexity class O(L^2) includes O(L) as a subset. If you're using L operations, that's still in O(L^2) it just also happens to be in O(L). — Craig Gidney 12 mins ago

@Omkar I basically computed the matrix exponential using an online software and plugged the parameters in the custom gate creation feature in Quirk. — Sanchayan Dutta 4 mins ago

Are you referring to FIG. S14 of the Supplementary Paper? Presumably with $\theta=45^\circ$ the gates would be half-way towards $\mathsf{CZ}$, which is known to have weaknesses in proving quantum computational supremacy. Indeed, they state "For example, $\mathsf{CZ}$ is less computationally expensive to simulate on a classical computer by a factor of two." — Mark S 15 mins ago

In order to make the exercise easier. — Craig Gidney 20 mins ago