I'm assuming you mean grab the qubit with the highest probability of reading 1? If so, you could repeatedly measure the qubits and select the one with the highest proportion (though this would be probabilistic). The DumpRegister method could also work, but you'd need an external program to identify the highest probability qubit — C. Kang 20 mins ago

Oh that is a nice idea actually, I could simply preserve the state of my register, and measure each qubit storing it in a list, then comparing to each other to find the highest probability. I am looking for a probabilistic outcome so I think this would work out. — Mridul 21 mins ago

Added as an answer! Hope the psuedocode helps :) — C. Kang 9 mins ago

Are you looking for a state in superposition? Or is the assumption that the state is a basis state? — C. Kang 20 mins ago

@GaussStrife #1: Yes, thanks, it was a typo. Fixed it (the choice of notation is to be consistent with Wilde's book). Also, the subscript $\sigma$ is just to emphasize the state for which we're computing the mutual information. #2: Yes, the upper bound is the "simple" one for the entropy (which holds for many entropic quantities). — keisuke.akira 7 mins ago

If the two qubits are connected physically, why it should not be possible to put two qubits gate on them regardless there are other gates connected to these qubits but via another connections? — Martin Vesely 3 mins ago

@JSdJ: Thanks for expanding my answer, plese feel free to post your comments as additional answer, I would vote +1 — Martin Vesely 7 mins ago

There are many non-unique ways to define gate fidelity, can you add a reference and the relevant details? In general, fidelity (of states) is a measure of their distinguishability: $F=1$ means that the states are identical, while $F=0$ means that a single measurement can distinguish them perfectly. Since many gate fidelities borrow the definition of state-fidelity, they tend to have a similar meaning. — keisuke.akira 15 mins ago

I think the easiest way is to consider the action of simple noise models like the phase damping map, which transforms the Bloch sphere to an ellipsoid along the $x$-axis; the depolarizing map which shrinks the Bloch sphere towards the origin (i.e., the maximally mixed state), etc. Then, one can understand more "complex" kinds of noise in terms of these "elementary" ones. For more details, I'll refer you to: Sec. VIIA of Lidar's notes. — keisuke.akira 20 mins ago

I am working on VS code with the QKD extension and a python host file — Jonathcraft 6 mins ago

I realised the problem was that the input was incorrect, but it helped when I checked that everything was fine. I am still getting used to the errors. The only thing that could be better is the line at which the error is (it always says line 0) — Jonathcraft 7 mins ago

I think you already have a good answer that catches the core concepts, feel free to add my comments though! — JSdJ 19 mins ago

... it looks to me, that the paper does not adress the fact that I trace out the system B. What do you think? — draks ... 15 mins ago

Comments are not for extended discussion; this conversation has been moved to chat. — heather ♦ 24 mins ago

+1 thanks. Funny I always used a kind of non-square matrix representation of a super operator $\hat P$ to do the trace-out job: $\rho_A= mat( \hat P \circ vec (\rho))$, it rather sums up amplitudes than settings things to zero... — draks ... 7 mins ago

That's certainly a useful way for computers to handle it, or if you want to deal with noisy operations e.g. via the Lindblad equation. But it's not generally the first choice for this sort of problem as converting backwards and forwards risks introducing extra work/mistakes (in my view). — DaftWullie 6 mins ago

Good point. Could the unitary applied in the paper to trace the ellipse on the surface simply not be extended to both systems via taking the tensor of the individual unitary, so that it works on the individual subsystems? From Fig.1 in that paper, the wording suggests that the ellipses they achieve on both the pure and mixed state case is what is generated from a unitary on the overall 2 qubit system, and then once the trace is taken, the ellipses is on both of their bloch spheres. — GaussStrife 17 mins ago

related: quantumcomputing.stackexchange.com/a/8479/55, quantumcomputing.stackexchange.com/a/13149/55 — glS 15 mins ago

it is equivalent, as pointed out here: quantumcomputing.stackexchange.com/a/13209/5280 — draks ... 23 mins ago

but still it looks like that the ellipse is drawn in the mixed/local&non-local $k-l$ plane, s. eq. 15. So my ellipse depends somehow on this initial state. Hmm, let's try... — draks ... 20 mins ago

I'm not familiar with Q#, but from the looks of it you could change the 'PauliZ' to 'PauliX' to check if the state is an eigenstate of the X operator - that's because the Hadamard transforms the eigenstates of the Pauli Z to the Pauli X operator (and vice-versa, btw) — JSdJ 3 mins ago

While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review — Mark S 15 mins ago

Wow, I didn't realise that it was that hard to test a chip. Its true that we don't have DumpMachine() in there :) — Jonathcraft 1 min ago

Thank You. I changed my version of Matplotlib from 3.3.0 to 3.2.2 and it solved the problem. — Shalabh Agarwal 4 mins ago

@Mridul: To clarify, simulators need not obey the no-cloning theorem, making it possible to get useful diagnostics when running on a simulator. DumpRegister doesn't violate the no-cloning theorem those diagnostics are displayed directly, and not used to condition the execution of a Q# program. Put differently, a Q# program can't ever "notice" a call to DumpMachine or DumpRegister, such that they can be safely replaced by no-ops on machines where that's not possible. — Chris Granade 2 mins ago

I'm not familiar with the test, but that does sound like adiabatic evolution, yes. If adding the "bomb" corresponds to creating an energy different between the two states, then it makes sense that slowly "rotating the system" causes the state to remain in the instantaneous ground state, which I guess here would be $|0\rangle$, only when the bomb is there — glS 23 mins ago