1:55 AM
I agree, but these days what is going to keep you more relevant in search and citations, quantum neural network (sounds pretty awesome) or a universal unitary approximator circuit. Don't get me started on the overuse and hype of 'data science' buzzwords! However there a flavours of neural networks, and the full term quantum protects it somewhat of trying to be a direct implementation of a classical NN, I'm not well versed in qnns but it may be that this is the closest type of approximator to a nn that you can achieve on a quantum processor, which somewhat validates usage of the term qnn. — Sam Palmer 2 mins ago
2:20 AM
Do you know for any video that explain all this, because I have hard time to understand it. Any video how IBM QC or D-Wave works at hardware level? Not math, but physics. Thanks. — guest 21 mins ago
1 hour later…
3:35 AM
Thanks! A couple of questions regarding the sampler solution: 1) Will it work if I replace the qasm backend with a real device? 2) Where do I specify the number of samples? — mavzolej 12 mins ago
2 hours later…
5:40 AM
Thank you very much @mariia for your concise explanation. That actually helped me a lot to clarify the doubts I had. If you don't mind will it be possible for me to get a reference for the points 1. and 2. for my further readings. — Adhisha Gammanpila 21 mins ago
1 hour later…
6:55 AM
The Bra Ket notation was displaying fine before I posted it. I am not sure what caused the error. — Abstract Acumen 5 mins ago
1 hour later…
8:10 AM
I see what you are saying about not being about to measure the bits in the other basis. I guess I was trying to come up with the importance of entanglement as it relates to the mathematics of the inequality. Without entanglement, there is not way to generate a column vector with multiple non-zero components. I was thinking that classical stipulates that the column vectors must be separable (no entanglement), thus preventing one from violating the entanglement. I was not considering the measurement basis. — Abstract Acumen 1 min ago
The purpose of my question was to enhance my understanding (and anyone else reading it) of this problem . My comments indicate the direction of my own research (by this I only mean relevant references that I found ) in this matter (which may or may not be relevant to the reader ). Abrams ' observations seem to indicate that an implementation is impossible. My opinion is that quantum gate teleportation might offer a glimmer of hope, but I am not sure (I am not an expert). I am still waiting for an expert level and definite answer. — Cristian Dumitrescu 11 mins ago
1) Yes it should, it can use the
QuantumInstance
like the other Aqua algorithms use too. 2) By passing a QuantumInstance
, I updated the answer above. Could you accept the answer, if your question was answered? :) It helps so others can see that this is resolved and a solution was found. — Cryoris 20 mins ago8:35 AM
@JSdJ: I meant that you do not operate with gates directly as on e.g. IBM Q. However, thanks for the comment. — Martin Vesely 10 mins ago
3 hours later…
11:55 AM
How does this answer the question? It is not asking if there is a 5-qubit code for 2 errors, it is asking for a distance 5 code. — Norbert Schuch 18 mins ago
12:20 PM
The perfect codes that you list are all distance 3. The reason for going to higher $n$ is to get more logical qubits, not greater distance. So, your final conclusion is incorrect. — DaftWullie 20 secs ago
this is my doubt "being in a superposition of only two basis states (|0⟩ and |1⟩), then is it considered as a superposition of 3 states, if not is the matrix a to attain superposition". — shashanka300 22 mins ago
What kinds of optimizations does Qikist do while using this method? For example, does it split the
WeightedPauliSum
into commuting sets, in order to reduce the number of measurements? — mavzolej 15 mins ago1:35 PM
1:55 PM
Also, the line
q_instance = QuantumInstance(backend, shots = shots)
generates the following warning, if the real hardware is used: WARNING - The skip Qobj validation does not work for IBMQ provider. Disable it.
. Do you know why, and how to avoid it? — mavzolej 21 mins ago2:45 PM
This has essentially been asked before. You probably want to take a look at my answer here: quantumcomputing.stackexchange.com/a/10282/1837 — DaftWullie 22 mins ago
3:05 PM
3:35 PM
@JSdJ More to the point: I do think that my comment (not answer!) catches a point: Parallelizing quantum computers is an entirely different thing than parallelizing classical computers. — Norbert Schuch 19 mins ago
@user1271772 Are you sure that's what the OP asks about? And yet, it has the same issue as putting together 100 single qubits: It does not scale up nicely. (BTW, your answer suggests that you can just combine two 100-qubit processors to get a 200-qubit processor. But this is only true if you connect them quantumly, and then you do have just one processor. The point is that "processor size" is a hard-to-compare figure of merit between classical and quantum computers.) — Norbert Schuch 22 mins ago
@JSdJ Regarding intricacies, if you don't ping me I don't get pinged ... — Norbert Schuch 24 mins ago
5:25 PM
5:45 PM
Why don't you just arbitrary prefactors to the identities so they sum up to $1$? — Norbert Schuch 3 mins ago
@user1271772 My point is rather that you make a certain assumption as to what the question is (without really explaining that you make this assumption); I don't think this is justified, it is not clear if the OP looked for that, and it might give a misleading impression ("an expert on SE said X, so it must be X"). — Norbert Schuch 6 mins ago
Just because sth. is ambigous, it does not mean it cannot be solved! For instance, the problem: What is the purification of $\rho$? is highly ambiguous. Yet, we can provide solutions, and even assess the nature of the ambiguity, and this is certainly a relevant and interesting and answerable problem! -- Basically, what you care for is a channel s.th. if the control register is 0, it is the identity, if the control register is 1, it does a certain channel. For any other control register you don't care. That seems well-defined and I would bet that there is always a solution. — Norbert Schuch 8 mins ago
@NorbertSchuch The asker is brand new to Stack Exchange, and might also be fairly new to quantum computing. Even one of our moderators here is still in high school. Can you not give them a break for not asking the question up to your standards as a senior researcher? As for connecting the processors: Say each chip is densely connected with many different gates allowed, but between the chips you can only do CNOT. Also: my answer should answer the question regardless of what OP meant. We are not yet investigating dual-QPU chips because we're not done optimizing single QPU chips. — user1271772 11 mins ago
@user1271772 I disagree. Or rather, I don't see the way in which you "connect them quantumly" such that it is not euquivalent in power to a 100-qubit processor, but also stronger than two parallel (classically connected) CPUs. -- But the issue with this question is that it is not even clear what the real question is. — Norbert Schuch 19 mins ago
@NorbertSchuch The two processors, connected quantumly, would be like a "dual-core processor". — user1271772 22 mins ago
@NorbertSchuch I see now what it is that you don't get. I wrote a bit about that here: the intra-chip connections in Sycamore have a topology defined in the picture in my answer. It's more densely connected than just, for example, putting a CNOT on the 4 grey qubits on the right-most edge of the picture, to connect it to the next Sycamore. What's the difference between a dual-core processor and a single-core processor twice the size? Surely it is that the intercore connections are far less than the intracore connections. — user1271772 10 mins ago
@user1271772 I still don't get the difference between connecting two sycamore chips with two-qubit gates and builting a 100-qubit version of sycamore. — Norbert Schuch 17 mins ago
"Why don't quantum computing scientists build two 50-qubit processors and connect them in parallel instead of building one 100-qubit processor?" I think I answered this without making any assumptions that need to be stated. My answer was: We can connect two Sycamore chips by some 2-qubit gates, but it's more worthwhile to first continue improving the Sycamore chips further. — user1271772 18 mins ago
@user1271772 I disagree. Making assumptions without clearly stating them is unscientific. — Norbert Schuch 22 mins ago
@NorbertSchuch Every answer on SE makes some assumptions about what the question is, without explaining that those assumptions are made. We are also not even sure if SE exists or if we are just hallucinating or in the middle of a long dream. In the end, to make any practical progress in this world, we have to make assumptions, and if we insist on explaining every assumption all the time, we will fall behind. If OP was looking for a different answer, they are very welcome to say so. The last part of your comment suggests my answer is harmful, but I do not see how it can be harmful. — user1271772 24 mins ago
Comments are not for extended discussion; this conversation has been moved to chat. — heather ♦ 20 mins ago
So you have a Hamiltonian like: $Z_1Z_2 + Z_1 - Z_2$ and you want to transform it into a Hamiltonian in terms of other Pauli matrices? — user1271772 23 mins ago
6:55 PM
7:50 PM
Do
QuantumInstance(backend, shots=1024, skip_qobj_validation=False)
but its just a warning and does not influence your code. — Cryoris 10 mins ago@NorbertSchuch The problem is that there's always many solutions, and they disagree about the behavior. You can define "controlling a channel" to be some particular mathematical operation, but it won't satisfy the criteria I laid out in the question (must be equivalent to controlling any unitary circuit implementation over system + environment). — Craig Gidney 14 mins ago
@NorbertSchuch I also considered that rule, and a few others. For each of them I found an operation where they gave the wrong controlled variant. For example, I wanted the controlled Reset's matrices to be [diag(1, 1, 1, 0), |10><11|]. Spreading out the matrix would have resulted in a different operation. — Craig Gidney 17 mins ago
8:40 PM
The Paulis are grouped in the
PauliExpectation
, it has an argument group_paulis
which can be set to False (True by default). The transpiler does some light circuit optimization by default, you can set optimization_level=3
in the quantum instance for the heavy optimization. See the expectation docs and quantum instance docs. — Cryoris 57 secs agoI'm not sure I understand your definition -- it seems, indeed, not well defined. My definition - which I would consider a clean definition - would be to say that the CP map $\mathcal E$ should be implemented when a control qubit is in the state $1$ and if it is in the state $0$, the identity is implemented. I think this is a completely clean definition, it will have a solution (in fact, many, and I'd bet one can classify the remaining degrees of freedom). -- The problem with the definition from the Stinespring dilation is that the latter is not unique. Of course you get non-unique results. — Norbert Schuch 17 mins ago
9:30 PM
@NorbertSchuch Aren't Kraus operators a representation of a CP map? My goal is start from a CP map represented as Kraus operators and derive Kraus operators that represent a controlled variant of the CP map. The problem I ran into is that "controlled variant" was ambiguous. — Craig Gidney 13 mins ago
Let's start more basic: Do you want controlled channels (CP maps) or controlled Kraus operators? — Norbert Schuch 15 mins ago
@NorbertSchuch I assert that your definition is ambiguous. I had the same intuition initially. For example, suppose the control qubit is the physical location of the system. Apply the operation just at location 0, instead of at both location 0 and location 1, and there! Controlled! But it turns out that this is not well defined, because equivalent mechanisms for performing the uncontrolled operation will no longer be equivalent in the controlled case. In circuit diagrams this manifests as unitary operations on the environment ending up controlled. — Craig Gidney 22 mins ago
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