Hi AHusain, I want to have a logical understanding of physical implementation of CNOT gate. Pl. refer to my comments on Mark's comment. — Ashish 6 mins ago

continued part... The moment a gate needs a Qubit's state to decide what operation to perform, it becomes difficult to understand implementation through resonators as given in papers because somehow they are not including explicit steps which I am used to reading in Algorithm literature... If you can point to a literature for layman then it would be great... The implementation of first type of gates like Hardamard makes sense but not Second type of CNOT gates... Pl. help. — Ashish 8 mins ago

Thanks Mark, I have some experience with Quantum Algorithms so I understand the working of CNOT gates theoretically, however when it comes to implementation, I am unable to follow as i find that there are two kinds of gates one are like Hadamard or Rotation gates which essential act upon qubits and does not need input from another Qubit. The other kind of gates are Controlled gates like CNOT which need input from at least one Qubit to act on other Qubit(s). I will continue... — Ashish 15 mins ago

Further, "control qubit is driven at the transition frequency of the target qubit", say if Control Qubit is in arbitrary state then what will be the effect of driving Control Qubit on its state? It would be great if you could point to a literature for layman where a logical understanding i.e. step by step procedure of physical implementation of CNOT is explained with examples on its behavior when Control Qubit is in arbitrary state & controlling multiple CNOTs. — Ashish 5 mins ago

Thanks, I will read and try to understand the attached paper and request you to go through my comments in response to Mark's comment. — Ashish 19 mins ago

Hi, I'm studying similar things, I was about to answer your question then I encountered a slightly different problem. The errors are unitary hence they are their own Kraus operators, also you're missing a piece of Knill-Laflamme condition, which implies that those errors are correctable, but introducing that piece led me to another contradiction so I posted another question — user2723984 12 mins ago

$\{E_k\}$ are the Kraus operators of the channel which describes the error - for instance, for unitary errors $U_k$ which occur with probability $p_k$, the channel would be something like $\rho\mapsto p_k U_k\rho U_k^\dagger + q\rho$, where $q$ is the probability that no error occurs. So if there are several unitary errors which can occur (or even just one error or no error), there is more than one $E_k$, and the first condition need not be satisfied for all pairs $E_k$, $E_l$. — Norbert Schuch 12 mins ago

I don't understand, $\{E_k\}$ are the Kraus operators of one error, not of all possible errors that can happen to the system, or have I misunderstood? — user2723984 14 mins ago

But is has to be satisfied for all error pairs $E_k^\dagger E_l$. Unless your error is always a fixed unitary. In that case, it can obviously be corrected, because you know what happened to your system. — Norbert Schuch 15 mins ago

$\mathcal{M}$ is a stabilizer (I think they're called like that, an abelian subgroup of the Pauli group, and we use as codewords eigenstates of matrices in $\mathcal{M}$ with eigenvalue $1$) the first condition, since there is only one Kraus operator, is always satisfied, since $U^\dagger U=I\in\mathcal{M}$ — user2723984 18 mins ago

Why would it mean that? The second condition is never satisfied. Why would the first be? (And what is $\mathcal M$?) — Norbert Schuch 23 mins ago

Then the condition is worded a bit weirdly I think. To me a double bit flip is "an error" and following this condition it is correctable. Should I take the condition to mean that an ensemble of errors is correctable only if the map induced by the most general linear combination of them has Kraus operators that satisfy the Knill-Laflamme condition? — user2723984 16 mins ago

thank you, I misinterpreted the condition as I was considering each possible flip an individual error that could either be correctable or not, rather than a general error. So I expected the condition to be fulfilled individually by single flip errors and not by double flips in the bit flip code for example. — user2723984 19 mins ago

@user2723984 In QECC, you look at the map which corresponds to an average error (including no error) during a given evolution. There is nothing weird about that. Indeed, the right formulation for that is a CPTP map with Kraus operators $E_k$, which are not unique -- an unknown error is nothing but a noisy evolution of the quantum system, nothing more. — Norbert Schuch 23 mins ago