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related: quantumcomputing.stackexchange.com/q/12212/55 (it's the same question in different notation) — glS 1 min ago
7:39 AM
the edit improves the answer, but it would be much better if you could make the post somewhat self-consistent, so that a reader doesn't have to read through the paper to get the basic definitions used in the question — glS 12 mins ago
8:29 AM
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1:20 PM
@CraigGidney The Kraus operator representation of a CP map is highly ambiguous, just as purifications and ensemble decompositions (all the same, basically -- Kraus operators come from ensemble decopositions of the Choi state). So if you want a controlled CP map, I am sure this can be defined, and it will certainly be even more ambiguous than the original Kraus operators themselves, since it is an ambiguity on a bigger space. I don't see any issue here. — Norbert Schuch 10 mins ago
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6:45 PM
Include the question and what you have so far. That makes this much easier to use for people in the future who will have the same question looking at this post. — AHusain 16 mins ago
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9:40 PM
What is X? And {Q,G,C} are all unknown variables? So you know the Hamiltonian in terms of symbols, but not in terms of the numerical values for each entry of the matrix? — user1271772 10 mins ago
@user1271772, Many thanks for your answer. What I have is from H (Hamiltonian)= in quadratic (XQX+GX+C) form and its variables (Q, G and C). What I would like is getting the Hamiltonian in the form of a list of Pauli terms. — Parfait Atchadé 17 mins ago
10:05 PM
X is the vector of the decision variables. Regrouping the terms in quadratic formulation X^T QX +g^T X +C of the Hamiltonian. In my case, H is the hamiltonian of the Vehicle Routing Problem. Q, G,C are all Known. I already calculated them. — Parfait Atchadé 21 mins ago
10:30 PM
I have already calculated 𝑋^𝑇𝑄𝑋+𝑔^𝑇𝑋+𝐶. I have n=4 elements. And the number the decision variables is = n*(n-1) = 12. — Parfait Atchadé 7 mins ago
Then you can calculate $X^T Q X + g^T X + C$. You will get a matrix of numbers, then you can use my answer to the question that you linked in your question. How many elements in the vectors? — user1271772 24 mins ago
10:55 PM
Okay. The problem is that Pauli matrices can only represent matrices that are 2x2, 4x4, 8x8, 16x6, 32x32, etc. You an represent your matrix with 2 qubits and 1 qutrit: This means 2 Pauli matrices and 1 Gell-Mann matrix for each term in the Hamiltonian. I will write an answer in some time. — user1271772 14 mins ago
11:45 PM
Maybe write it with 16x16. Because it doesn't make sense to use less qubits for 12x12. Don't you? — Parfait Atchadé 2 mins ago
If it's a 12x12 matrix, you're dealing with 2 qubits and 1 qutrit. IBM does not allow qutrits. You might want to modify your problem so that it deals with 3 qubits (8x8 matrix) instead of 2 qubits and 1 qutrit (12x12 matrix). — user1271772 7 mins ago
Come to think of it, I think I need decomposing into Pauli matrices to implement it in IBMQ. Do you think there is no way to decompose into Pauli matrices? — Parfait Atchadé 22 mins ago
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