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Can you help to clarify what you have done already? Where are you confused? Are you asking if, being in a superposition of only two basis states ($\vert 0\rangle$ and $\vert 1\rangle$), then why would $\vert *\rangle$ be a qutrit? We want to help but please clarify what you are confused about? — Mark S 20 mins ago
This is a slight detour to what the question asks, but there are instances where Hamiltonians need not be Hermitian. A slightly weaker condition of PT symmetry actually suffices and it gives rise to a broader range of functions for analysis. For starters, one can look at arxiv.org/abs/hep-th/0703096 — Yuzuriha Inori 23 mins ago
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Asked and answered in the book Quantum Computing: A Gentle Introduction, chapter 12 exercises; is this a homework question? — Rob 11 mins ago
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Thank you for your suggestion @MStern . My answer would not be as good as Abrams observations in the link above, the interested reader can read his thesis (OR the relevant pages ). I wonder though whether quantum gate teleportation, the possibility to apply a quantum gate to an unknown state during teleportation could solve this problem. quantumcomputing.stackexchange.com/a/1810/10110 Basically, each iteration would be represented by such a quantum gate teleportation (back and forth ) between two systems A and B. I don't know if this solves the problem, but it's worth a look — Cristian Dumitrescu 14 secs ago
Concerning D-Wave, it is not gate-based quantum computer, so question how it implements Rz gate is irrelevant. — Martin Vesely 17 mins ago
I like the fact that you can keep a record of the corrections and apply them later. — Cristian Dumitrescu 13 mins ago
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A little bit off-topic, but I was wondering about your statement 'similar to how there is a convention around how unobservable ... when controlling unitary operations.' If U is any unitary, is the convention then to take the representative of U in SU? — JSdJ 6 mins ago
I tried to access thru a web-IDE and it worked without problems. Someone knows where can I find the settings or the file in the package? — Ruben Alfonso Casillas Pacheco 10 mins ago
In D-Wave system's, the effective Hamiltonian of the entire system is changed so that the answer of the question is encoded into the ground state of that Hamiltonian. Applying a gate in any gate-based quantum computer is also effectively changing the Hamiltonian, invoking a rotation around an axis or a coupling between certain states. The same goes for the adiabatic quantum computer - there are no gates, per se, but the phases of qubits (i.e. parts of the Hamiltonian) still might need to be changed to arrive at the desired full-system Hamiltonian. — JSdJ 15 mins ago
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yes,this is what i mean, From Solovay-Kitaev, I know I can realize any single qubit with{Hadamard,Phase,pi/8} with accurcy 𝜀, and in real hardware, what is the reliable accurcy? — Henry_Fordham 3 mins ago
Hi Henry_Fordham! Could you elaborate a little more your question? Do you want to know the theoretical accuracy we can achieve with Solovay-Kitaev, the practical accuracy on a real hardware, something else? — Nelimee 10 mins ago
"Quantum Computing verstehen" means "To understand Quantum Computing" (German). — peterh - Reinstate Monica 12 mins ago
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But then where would you use the k from $U = \sum^{T - 1}_{k=0}$ $|k\rangle$ $\langle k |$ $ \otimes$ $e^{i A k}$ ? (in the code that
j
which you mentioned was actually this k
, sorry for the confusion). I thought the simulation time depends on that variable, since you will basically have 4 unitaries of the form e^(iAk)
and k
changes (when you use MultiplexOperationsFromGenerator
). — Martin 17 mins ago11:10 AM
@JSdJ The convention is to include an unnecessary detail in the definition of the original gate (the global phase) and then use that to decide the relative phase of the controlled operation. It's such a natural thing to do that it's almost not worth even calling it a convention. — Craig Gidney 14 mins ago
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@Rammus I had a look at that wiki article and went back to my book to look for "controlled gates", and they actually briefly cover it. Thanks alot for the tip, sometimes i'm just missing a keyword to google for :) — FelRPI 4 mins ago
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You're right, in the paper, they compute the expectation value of Y. Since I am implementing this on a simulator, I run the circuit multiple times and compute the probabilities just like you mentioned. However, the simulator only does measurements in the computational basis, hence my question — Skyris 4 mins ago
FelRPI No problem, congratulations on working it out :). @Oldville The classical bit is presumably encoded into a qubit in the compuataional basis via $ a \mapsto |a\rangle$. — Rammus 8 mins ago
The figure is quite confused: the controlled H is fed with a classical bit and controlled by a classical bit, but produces a quantum state. — Oldville 14 mins ago
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[ Boson ] New comment posted on stackoverflow by [Shahbaz ](stackoverflow.com/users/13397262/shahbaz)
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I see, no there is currently no way to not use the
Parameter
class. That used to be possible but was removed because there was no use-case where Parameter
did not work. You open an issue on GitHub to address this :) However there are ways to calculate expectation values, its actually quite easy. Check out this notebook. — Cryoris 3 mins ago5:10 PM
The
SnapshotExpectationValue
is developed to be fast. It computes the expectation value via matrix multiplication, not using shots. — Cryoris 22 mins ago6:00 PM
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to answer your question more directly, to me the definition of a neural network, now more a buzzword, is the application of a parametrisable combination of functions used to approximate a target function, whether this is 'wires and weights' or rotations. — Sam Palmer 5 mins ago
The transfer function for each perceptron is a non-linear function that takes a linear combination of inputs to produce an output. In the simplest case we try to approximate a function using as linear combination of functions (perceptrons). In qnn we already have our transfer functions defined ... they are our unitary rotations. Arbitary unitary operators can be decomposed into a sequence of controlled rotations, hence in a qnn we aim to approximate the function, an arbitary unitary, by searching for the sequence of rotations, in this case our parameters to adjust are the angles. — Sam Palmer 18 mins ago
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whether that's enough to justify the terminology, is a matter of opinion. IMHO it is a bit of a stretch, but others will disagree. Regardless, I don't see how this question can be answered objectively, in lack of a strict definition of what a "QNN" should be (which there isn't). Also, @Skyris each post should contain a single question. You can create different posts to ask different questions. — glS 4 mins ago
@SamPalmer but, if I'm reading the paper correctly, there is a crucial difference in that there is no nonlinearity in these "QNNs". In NNs, the nonlinearity component is pivotal, lest the whole function being linear and not able to capture complex patterns. There is nothing of that in the QNN (nor there could be, unless measurements are introduced). Their circuit is trained to reproduce unitary relations between input and output states. Tbh the only thing I see in common with NNs is the use of a parametrisation in terms of a sequence of trained maps.. — glS 8 mins ago
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Ok, thanks, now I understand a little better what you are trying to do. So I also see your original code doing something non-trivial if I just replace
IntAsDouble(j)
with something like IntAsDouble(j+1)
or even IntAsDouble(j-1)
. It isn't immediately obvious to me why this is happening, but my guess is that there is some subtle bug in your implementation where the unitary is only actually getting applied for the j==0
case. Do you need to ensure that both registers are in superposition before applying the unitary? e.g.: ApplyToEach(H, input); ApplyToEach(H, register);
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