12:39 AM
No, sorry. I clarified the question with what I expect to be the density matrix in order to have consistence. — leimer0rozzh 9 mins ago
Hi Christian, welcome to QCSE. I've taken the liberty of formatting your question into latex, I hope I didn't miss anything. You can see how I've edited it by reviewing the edit button. As to the question "Is back in time (classical ) information transfer possible?" the answer is "no", but it's not entirely clear from the question what you are asking of Victor, Alice, and Bob. It seems like your approach must invalidate the monogamy of entanglement somehow. When Victor entangles his photons, Alice and Bob don't care. — Mark S 15 mins ago
4 hours later…
4:24 AM
is that dot with the phi angle represent a rotation matrix with that angle? — Enrique Segura 8 mins ago
3 hours later…
6:54 AM
When Victor entangles his two particles 2&3, Alice and Bob will measure perfectly random outcomes on their particles 1&4 (taken separately they are insensitive to what Victor does). But they can use coincidence circuits locally, and when alpha is close to 1, with high probability their measurements will be anti-correlated (0, 1), (1, 0). This can be seen from the last relation in my question. I just follow the same experimental scheme as in the reference. The difference is that I start with a different entangled state for particles 1&2 and also 3&4. — Cristian Dumitrescu 13 mins ago
Thank you @MarkS for latex formatting my question. Before the Bell-state measurement particles 1&2 also 3&4 are entangled. After Victor performs his Bell-state measurement on particles 2 & 3, they become entangled, also particles 1&4 become entangled. Entanglement is redistributed among the 4 particles. This scheme does not contradict the monogamy of entanglement. Please see the reference . — Cristian Dumitrescu 21 mins ago
7:19 AM
Taylor series for $\sqrt{1+x}$ doesn't help to expand $\sqrt{x}$ at 0. So, if some matrix $A$ has zero eigenvalues then $\sqrt{A}$ can't be expanded in a series, in general. The simplest example $A = \begin{pmatrix} 0 & 1 \\ 0 & 0 \end{pmatrix}$ doesn't have square root at all, so it can't be expanded. — Danylo Y 1 min ago
If we consider Everett's many worlds interpretation of QM (or variants ), there is nothing sensationalistic about transferring information back in time (for lack of better words ), no premonition, no winning the loterry, none of that. You still can't predict the outcome of particular events. What you could do though (If my calculations are correct) is to have access (almost instantaneously ) to the result of long deterministic computations (for example ). I would call that progress, whether we are talking about classical or quantum computing. — Cristian Dumitrescu 16 mins ago
8:09 AM
Hi Enrique. How I understand VQE one doesn't need to evaluate the Hamiltonian H. One needs to represent H as a sum of Pauli terms and try to find the expectation values of each Pauli term without evaluation. Here is a link to my tutorial for VQE, where I didn't evaluate the Hamiltonian or a part of it. github.com/DavitKhach/quantum-algorithms-tutorials/blob/master/… — Davit Khachatryan 13 mins ago
I just hope that an expert will consider this question seriously, and tell me whether I am missing something important, either theoretical or related to the experimental implementation of this scheme. — Cristian Dumitrescu 16 mins ago
8:34 AM
In VQE we are changing the prepared state. And we don't evaluate $XX$ or $YY$, we just measure the $\left\langle \psi \right| XX \left| \psi \right\rangle$, where $\psi$ is our prepared state. How calculate the $\left\langle \psi \right| XX \left| \psi \right\rangle$? We just simply measure what is the probability of measuring eigenvectors of $XX$ that have +1 eigenvalue ($\left| ++ \right\rangle$, $\left| -- \right\rangle$) and substarcting the probability of measuring eigenvectors of $XX$ that have -1 eigenvalue ($\left| +- \right\rangle$, $\left| -+ \right\rangle$). — Davit Khachatryan 1 min ago
One question do you want to find minimal eigenvalue of your presented $H_{total}$? If yes then why you are changing it with $\theta$s? I think $H_{total}$, in that case, shouldn't be changed — Davit Khachatryan 2 mins ago
I am actually a bit confused. I am wondering how I can in one circuit have the hamiltonian rather than what I am currently doing: creating two circuits, one representing XX + YY since they commute, and another representing ZZ? — Enrique Segura 22 mins ago
8:59 AM
Enrique did you see this presentation? youtube.com/watch?v=E947xs9-Mso If not I highly recommend you to check it out, because there you can find an example of preparing ansatz(trial) state for two qubits and see how he deals with one of the Pauli terms from given Hamiltonian. — Davit Khachatryan 12 mins ago
I am still unsure about how develop Ansatz to be able to present the original hamiltonian - before decomposition. — Enrique Segura 20 mins ago
2 hours later…
11:29 AM
3 hours later…
2:24 PM
Is there any function in qiskit to see stavevector in the end of the circuit?@Matthew Treinish — vardhan negi 12 mins ago
Is there any function in qiskit to see stavevector in the end of the circuit?@Matthew Treinish — vardhan negi 12 mins ago
5 hours later…
7:24 PM
You'll have to use the statevector simulator, something like: ``` from qiskit import Aer from qiskit import execute from qiskit.circuit.random import random_circuit qr = random_circuit(10, 10, max_operands=3) backend = Aer.get_backend('statevector_simulator') sv = execute(qr, backend).result().get_statevector() print(sv) ``` — Matthew Treinish 8 mins ago
8:07 PM
8:34 PM
8:44 PM
You want Victor to make a local operation on his two qubits $2$ and $3$, in such a manner that two other parties Alice and Bob can perform local operations on their qubits $1$ and $4$ and compare statistics among each other, such that Victor's local operations alone are sufficient to send a signal to Alice and Bob such that their statistics will vary based on Victor's local operations. That is, you want Victor to send a signal to the system of (Alice and Bob). I don't think you can do what you want to do locally. — Mark S 10 mins ago
There are two operational modes. In one mode photons 1&2 also 3&4 are entangled. In the second mode of operation photons 2&3 also 1&4 are entangled. The coincidence probability distributions for Alice and Bob measurements (using coincidence circuits only locally ) are slightly different in these two operational modes, but only if $ \alpha$ is different than $\beta$ , and $\alpha$ is not 1. The no- signalling theorem does not cover this case when there is an entanglement redistribution between the four particles. — Cristian Dumitrescu 23 mins ago
9:29 PM
Please check the calculations in detail when alpha =/= beta and alpha =/= 1. A Bell state measurement is an entanglement measurement, it is not the standard type of measurement that the no-signalling theorem deals with. I admit that I could have made an error in my calculations, but they indicate that the scheme works. — Cristian Dumitrescu 21 mins ago
9:54 PM
10:19 PM
Hi @Rune. Can you include a bit more information about the data that you are trying to process again? Is it the data from several shots of measurements in a quantum circuit? And where did you obtain the json file that you downloaded? — eqb 21 mins ago
11:54 PM
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