please dont close the question if your are in capable of answering it,i am hopeful some will be able to understand — shashanka300 11 mins ago

After some effort, I found Abrams' PhD Thesis (partial, freely available on the Internet ) in which there is an answer to my question, pages 79-80 dspace.mit.edu/bitstream/handle/1721.1/85313/… — Cristian Dumitrescu 13 mins ago

That means that you have to track the relevant qubits that carry the information you are interested in, and measure the qubits (including ancillary qubits) that you are interested in only in the final stages of the algorithm. I don't know whether that's possible. — Cristian Dumitrescu 9 mins ago

If you use higher dimensional Hilbert spaces in order to imbed the nonlinear gate into higher dimensional unitary gates, then you cannot measure the garbage ancillary qubits at intermediate stages of the algorithm because you need to make sure the states can interfere with each other in future iterations. — Cristian Dumitrescu 13 mins ago

Unless you can find a way to guarantee that all the other computational paths are innocuous (or at least with high probability ), that is they don't drastically decrease the number of states with a $\vert 1 \rangle$ for the final qubit. — Cristian Dumitrescu 3 mins ago

That means that you have to track the relevant qubits that carry the information you are interested in, and measure the qubits (including ancillary qubits) that you are interested in only in the final stages of the algorithm. I don't know whether that's possible, probably not, because the computational path you're interested in would have very small probability. — Cristian Dumitrescu 16 mins ago

You get to something like a "superposition of computational paths", admittedly a poor characterization on my part, but intuitive. — Cristian Dumitrescu 10 mins ago

Thanks for your reply! So I would have to do a controlled rotation specifically on |01> and |10>? Why isn't it enough to do a controlled rotation on the entire register which contains the binary representations of the eigenvalues? — Martin 55 secs ago

Can you see providers if you go on the IBM Quantum Expereince? — met927 9 mins ago

That would also work, but it would mean creating a new circuit, but if you are fine with doing that it should work — met927 11 mins ago

Could you explain how exactly I should do it this way? — mavzolej 16 mins ago

You could iterate over QuantumCircuit.data() which returns a list like object of (instruction, qargs, cargs). You should then be able to do new_circuit.append(instruction, qargs,cargs) — met927 23 mins ago

Indeed, if I go to the web-dashboard I can see my past jobs. — Ruben Alfonso Casillas Pacheco 19 mins ago

Thanks for answer! — MrFa1n 16 mins ago

That would be the 'lazy' and non-optimal but easiest to understand approach, but you can always optimise the gates. For example, here it would be enough to use 1-controlled rotations by either the first or second qubit since no representation contains two 1's. However, if you mean one single controlled rotation, that wouldn't work (exceptions aside) since for different values you have to rotate by different angles. In general, for n qubits and $2^n$ possible eigenvalues it is enough to use $2^n$ single controlled $R_y$'s, and the angles can be found using e.g. the UniversalQCompiler. — user96233 14 mins ago

You can answer your own question then. — M. Stern 1 min ago

I think CV quantum computing is about the weakest example where infinite dimensional spaces are really required -- after all, these are all separable Hilbert spaces and can thus be well approximated by finite dimensional spaces (though this might not be a very nice description). Generally, QFTs should make a much stronger case for the requirement for infinite dimensional spaces. — Norbert Schuch 18 mins ago

By QFT in this context , I take you mean lattice gauge theory or something to that effort? And yes, I agree that all of these spaces are separable, but OP really wanted to see if there was any use, and I just pointed out that there are. That they can be finitely approximated is a separate issue. — Yuzuriha Inori 44 secs ago

Thanks for just an incredibly thorough answer! — meowzz 11 mins ago

it says those are "nonnormalizable states". In other words, they don't represent physical states, they are just mathematical tools — glS 15 mins ago

Thanks for the insightful answer. "The limit of infinite squeezing corresponds to the uncertainty of one observable being zero and the other one being infinite" makes sense to me, however I was reading through this paper (arxiv.org/abs/quant-ph/0008040) & it mentions states that are "infinitely squeezed in both position and momentum". Could you possibly comment on that? — meowzz 16 mins ago

@YuzurihaInori Well, no lattice, in particular. -- Again, I think it depends what you (or the OP) mean by "in practice". I think that there is a significant number of theoretical physicists who think that anything can be done with finite dimensional spaces. And CVs for a finite number of modes is a prime example: If you truncate to a finite number of bosons, you pretty much get everything what you want. Another one of these examples are spin chains: Most things can be captured very well by sequences of finite lattices for $N\to\infty$. — Norbert Schuch 20 mins ago

Got it. In that state would you not be able to measure position and momentum? — meowzz 11 mins ago

@meowzz you wouldn't be able to "measure" anything about them, as they are not physical states — glS 54 secs ago