What do you mean by "two qubits in the one state"? If you have two qubits in the state $\vert 01\rangle$ then these two qubits together may correspond to binary $1$. It's not clear to me wny you refer to "two qubits in the one state" as vectors $(0,1)$ and $(0,1)$... — Mark S 8 mins ago

Could you post the QAOA tutorial you are following? Would make it easier to explain if we know how they are discussing things. — Dripto Debroy 16 mins ago

Please refer to this link on some details of the initialization. Basically, it only guarantees the transformation from all-zero state: github.com/Qiskit/qiskit-tutorials/blob/master/tutorials/… — Rudy Raymond Harry Putra 3 mins ago

This answer might be interesting quantumcomputing.stackexchange.com/a/11665/9459 — Davit Khachatryan 6 mins ago

are you asking specifically why they are called like that, or are you asking what they are used/useful for? The "shift operator" terminology is pretty self-explanatory: $X$ shifts the state it acts on (as in, it sends $1\to 2$, $2\to3$ etc). About the boost, I've more often seen those called "clock matrices", e.g. here. I guess a reason for the name is that the phases of the eigenvalues behave like time in a clock (i.e. they live in a modular space) — glS 1 min ago

Thanks a lot. Your last paragraph was banging away as a question mark at the back of my skull as I read everything preceding it. Just a few things to clarify - maybe you can confirm or correct me: (1) Even if the Hamiltonian has non-commuting terms, it still has eigenstates, so the last sentence of your para2 holds even in that case right? (2) If you start off in a state that's not an eigenstate, and use a time-independent Hamiltonian, you will never end up in an eigenstate, so whatever's happening to the state is very quantum. This again, is true regardless of terms commuting or not. — Alexander Soare 13 mins ago

So all the simulator or emulator decompose a unitary gate in that way? Thx — Henry_Fordham 1 min ago

@AlexanderSoare (2) Yes, that's exactly correct. For a Hamiltonian with commuting terms, only the energy eigenstates can be even loosely thought of as "classical". — tparker 59 secs ago

@AlexanderSoare (1) Yes, that's true, but if the terms don't commute, then each individual term in the Hamiltonian doesn't necessarily have a well-defined energy in an energy eigenstate (even if the entire Hamiltonian as a whole does). So this is conceptually quite different from a classical energy function, where you're typically just adding together a bunch of scalar functions. You can't decompose the scalar energy function into a sum of simpler energy functions, as you can in a truly classical problem. — tparker 1 min ago

In Qiskit, you may either build the circuit from the scratch by adding gates, or by providing the unitary matrix of the circuit and decompose it using iso(). As I wrote in my answer, decomposition is independent on whether you want to run the circuit on a real backend or in a simulated one. Once you have the decomposition, then you choose the backend. — Michele Amoretti 22 mins ago

Nice getting the requirement of surjectivity - people often miss that. But doesn't boundedness follow automatically from the norm-preserving property? Is that why you put "(bounded)" in parentheses? — tparker 14 mins ago

Usually, you choose the universal quantum gate set depending on the backend you are using. For IBM Q backends, the most general single qubit gate is $U_3$ (qiskit.org/textbook/ch-states/…). In Qiskit, to compile your circuit using specific gates (e.g., CNOT and $U_3$), you need to use the transpile() function: qiskit.org/documentation/stubs/qiskit.compiler.transpile.html — Michele Amoretti 4 mins ago

So after decompose it into CNOT and single qubit gate as the paper mentioned. How to decompose the single qubit gate into universal quantum gates set? like Clifford +T, Thx — Henry_Fordham 18 mins ago

So, the universal quantum gates {Clifford +T} is not commonly used in any backend or simulated one anymore, right? I read the reference you sent, one U3 gate seems can represent any single qubit gate, However, in SK algorithm, by running the C++ code, the H and T gate grow exponentially. so if the basic gate set canbe {U3 and CNOT}, why we need {Clifford+T},like in SK-algorithm or some of its optimization. — Henry_Fordham 3 mins ago

@glS I am asking about both. You have explained "shift" very clearly and introduced me to another name of "clock matrices". You should write it as answer and it can be updated when we know clearly about "boost" also. Also, I don't understand how is "Z pauli matrix" a clock matrix when it does not have any \omega. — Divy 2 mins ago

@glS I guess the name relates to Lorentz boosts. — Norbert Schuch 3 mins ago

You have to be more clear in making questions. What is SK algorithm, what is the C++ code you refer to? I have not such references, so I cannot help with your last question. — Michele Amoretti 6 mins ago

What are SK algorithm and the C++ code you refer to? I have not such references, so I cannot help with your last question. — Michele Amoretti 3 mins ago

Sorry yeah that was my typo including the sum over r as well, I was just trying to get the sum over m to vanish, which seems to work! Thanks for clarifying! — Sam Palmer 18 mins ago

I understand when $x$ is a fixed classical input, but I am concerned about the case when it is a superposition, in particular the uniform superposition of all $n$-bit strings. — taninamdar 14 mins ago

The TNICP map that projects onto the positive eigenspace of your density matrix should do the trick I think. — Rammus 12 mins ago

Sorry, I should have clarified in the question but I meant a CP map that works for any input $\rho$, not just a specific one. That is, it always checks if any eigenvalues are smaller than $\delta$ and sets them to zero if this is so. Is that possible? — user1936752 12 mins ago

@user1936752 Linearity should instantly imply that "no". (For instance, just apply the map to $10\rho$ instead of $\rho$!) But before I take the effort to write this in an answer please ask this in a clean and formal way in the question. — Norbert Schuch 23 mins ago

With your edit, it makes no sense. The way you write it the map should neither depend on rho nor on $\delta$. Or is this what you really mean? Please write a formal statement (which means: a formula, with clear statements on what the map can depend.) -- For instance, a formal statement would read: "For every delta, there is a CP map E such that for all rho, XYZ holds." — Norbert Schuch 24 mins ago

@Rammus and Norbert Schuch, thank you - your answers to both this and the old question were helpful! — user1936752 20 mins ago

Just edited and added the tutorial. (=> qiskit.org/textbook/ch-applications/qaoa.html) — César Leonardo Clemente López 22 mins ago

Much better! I guess what is missing is that you want that $\sigma=P\rho P^\dagger$, where $P$ is the projector onto the eigenvalues of $\rho$ larger than $\delta$. — Norbert Schuch 23 mins ago

We express the superposition as the sum of certain basis vectors; thus each term of the sum has x being a single basis vector and will not be in superposition. If you do the computation term-by-term, you'll see that the garbage qubits end up unentangled from the rest. — Mariia Mykhailova 20 mins ago

arxiv.org/pdf/quant-ph/0505030.pdf, this paper is about THE SOLOVAY-KITAEV ALGORITHM, which told us a any unitary single gate can be decomposed into {Hadamard, Phase} with any accuracy 𝜀 , the number of {Hadamard, Phase} grows exponentially as the 𝜀 becomes accurate, and the result is approximated decomposition. However, in your reference, the U3 gate seems exacted decomposition which means only one U3 gate can be realized any unitary single gate. If so, why so many people still need approximated decomposition and optimize it to shorten the approximated sequence of {Hadamard, Phase} — Henry_Fordham 23 mins ago