This is very good news! Can you provide a link to the documentation of the simulation of noisy qubits? — Michele Amoretti 1 min ago
Thx, have you ever read this paper arxiv.org/pdf/1206.5236.pdf, it told me he found a specific sequence of universal set, but actual I still do not get it. Lol — Henry_Fordham 17 mins ago
5:30 AM
This does not really answer the question. If you have a different question, you can ask it by clicking Ask Question. You can also add a bounty to draw more attention to this question. - From Review — Martin Vesely 4 mins ago
Please see this question: quantumcomputing.stackexchange.com/questions/11861/…, it can help. — Martin Vesely 22 mins ago
9:20 AM
5 hours later…
1:55 PM
Thank you again. I still have a problem because when I run the code I get the following error: The Qobj uses gates (['h', 'sdg']) that are not among the basis gates (['u1', 'u2', 'u3', 'cx', 'id']) [1106]. I have unrolled the quantum circuit object in these basis gates and I have checked that it has been done propertly. Anyway it does not work. — Paula G 16 mins ago
2:20 PM
@Henry_Fordham The early parts of that paper deal with exact decompositions of unitary matrices with entries in certain ring extensions (i.e. exact decompositions of a discrete subset of unitary matrices into a discrete set of gates). The latter sections deal with approximate decompositions of arbitrary unitary matrices into a discrete set of gates, which is a specific implementation of the Solovay-Kitaev algorithm. Feel free to ping me in chat if you have general questions on the paper you want to talk through. — Jonathan Trousdale 5 mins ago
(All that having been said, I think that most of the times that actually practitioners use the term "classical computer", they aren't thinking these big philosophical thoughts - they're just going along with the standard convention.) — tparker 17 mins ago
3:10 PM
3:35 PM
I don't think they have to be in superposition, I tried to place them just in case to check, but that didn't fix it, so I'm probably making a mistake somewhere else in my code.. Thanks for the idea though! — Martin 20 mins ago
Based on the direction you're headed in your edit, you might be interested in looking into tensor networks. As you noted, Hilbert space is huge (exponentially so), but physically relevant regions of Hilbert space are constrained by locality. This paper is a nice introduction, section 3.4 in particular is directly relevant to your comments above. — Jonathan Trousdale 24 mins ago
3 hours later…
6:30 PM
This question How to compute the tensor product of the depolarizing channel with the identity? gives you the method. Apply it to the first state and then the second afterwards. By the way, the second equation in your question is not well-defined. I think you want to write $(\mathcal{E} \otimes \mathcal{E})(|\Phi^+ \rangle \langle \Phi^+|)$. — Rammus 5 mins ago
Has it been proved that classical analog computers can be efficiently simulated. There's a recent Nature paper that suggests not nature.com/articles/s41467-018-07327-2 — James Wootton 14 mins ago
3 hours later…
9:25 PM
...that said, I'm not sure if we couldn't get much larger speedup with analogue computers based on PDEs rather than ODEs. — leftaroundabout 15 mins ago
@JamesWootton that paper actually does use digital simulation for the results presented. Yes, the digital simulation of ODEs incurs discretisation issues, but with a suitable choice of solver these can be kept in rigorous bounds that are not asymptotically worse than what you would also get in an analogue implementation due to shot- and thermal noise. You do get a (possibly quite large) overhead though; in particular digital computers have a substantial energy consumption due to the need to drive transistors back and forth even in steady state of the ODE. — leftaroundabout 18 mins ago
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