1:00 AM
@Davit, could you please provide a modified version of your code in which only certain $Z$s (from the provided list, say
z_list=[0,3,4]
) would be measured? Thanks! — mavzolej 6 mins ago1:50 AM
I'm confused why $S\vert 2\rangle=\vert*\rangle=\frac{1}{\sqrt 2}\vert 0\rangle-\frac{2}{\sqrt 2}\vert 2\rangle$. Are you asking where $-\frac{2}{\sqrt 2}$ came from? That seems like a typo in whatever image you copied this from. The correct state should probably be $S\vert 2\rangle=\vert*\rangle=\frac{1}{\sqrt 2}\vert 0\rangle-\frac{1}{\sqrt 2}\vert 2\rangle$. There you have $\langle *\vert *\rangle=1$. — Mark S 12 mins ago
2 hours later…
4:17 AM
5:07 AM
5:57 AM
6:27 AM
6:50 AM
yes it its from a paper. I agree about the typo but is it a valid super position state for a Qutrit — shashanka300 6 mins ago
7:37 AM
7:47 AM
I didn't expect an answer directly from you, it was a pleasant surprise :) anyway now everything is clear, thank you very much! — Rik 22 mins ago
8:17 AM
8:27 AM
@mavzolej, I have changed my answer, now it includes the case described in your comment. — Davit Khachatryan 14 mins ago
9:37 AM
9:57 AM
11:07 AM
11:25 AM
Please, provide an example of a conditional gate. One of the most famous conditional gates is $CNOT$, but note that it is a two-qubit gate, and the question assumes that there are single qubit conditional gates (at least that's how I (maybe mistakenly) understand the question). — Davit Khachatryan 5 mins ago
11:50 AM
This comment unfortunately does not answer the asked question, as that is specifically on the real-world implementation of quantum simulations. — JSdJ 9 mins ago
12:40 PM
While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review — Nelimee 7 mins ago
2 hours later…
3:10 PM
@Davit, amazing, thanks!! I guess, the list in your example should be
[0,1]
, using Qiskit notations?.. Also, is my understanding correct that in order to measure an arbitrary Pauli, the only extra step would be adding an additional layer of rotations to the quantum circuit before measuring, conditioned on which particular Pauli is to be calculated? — mavzolej 23 mins ago4:00 PM
What exactly does the line
bit_indexes.sort(reverse=True)
do? (and why do we need it?) — mavzolej 7 mins agoPerfect, thanks! TBH, I'm a little surprised that this whole procedure is not included into standard Qiskit library. — mavzolej 11 mins ago
@mavzolej, happy to help :) I think the ordering is ok, it can be checked with the link that I have added in the answer. Yes, you are right, note that I have added a small explanation for the arbitrary Pauli term. — Davit Khachatryan 13 mins ago
4:25 PM
Could you please also explain why
cut_counts
produces a reduced number of counts? Shouldn't just some of the original counts be counted multiple times? — mavzolej 14 mins ago@mavzolej, it sorts the indexes in decreasing order. It is added because if the function has received
[0, 5, 1, 2]
indexes, it will need to reorder them and it does reordering in decreasing order [5, 2, 1, 0]
because that is the order that the for
loop that uses bit_indexes
needs in the current implementation. — Davit Khachatryan 22 mins ago
1 hour later…
5:40 PM
Can you please edit your question to include the code you're trying to run? It's really hard to troubleshoot errors without the code that produces them. — Mariia Mykhailova 14 mins ago
6:05 PM
@AlexanderSoare, I know the paper and how I understand sometimes/often people drop the $\otimes$ symbol, and in this particular case they also have dropped the $\otimes$ symbol. So in equation (1) they have tensor products. — Davit Khachatryan 3 mins ago
I could be confused here, but I'm not actually referring to the tensor product (which would be for the 2-qubit case). I'm talking about the operator which is formed by the sequential application of $\sigma_z$ then $\sigma_y$, which is what I understand the paper means with equation (1) from my original question. — Alexander Soare 8 mins ago
6:30 PM
Alexander, the equation (1) (or slight modification of it) is applicable also for one qubit case: for one qubit $H = \sum_{\alpha} h_{\alpha} \sigma_{\alpha} = h_i I + h_x \sigma_x + h_y \sigma_y + h_z \sigma_z$. — Davit Khachatryan 2 mins ago
Ah understood, I had the whole premise wrong. Thank you! I will accept your answer although I suppose it may make sense (if you have time) to add an edit fully clarifying this last part for anyone else who might have my issue. — Alexander Soare 12 mins ago
A quote from the paper: "Any Hamiltonian may be written as", it already means that the equation (1) is not written only for the one qubit case. — Davit Khachatryan 24 mins ago
6:55 PM
And in the second (similarly for the third) sum of the equation (1) we don't have separate $h_{\alpha}$ and $h_{\beta}$, instead, there should be $h_{\alpha \beta}^{ij}$ that is not (necessarily) equal to $h_{\alpha}^i \cdot h_{\beta}^j$. — Davit Khachatryan 14 mins ago
7:20 PM
The example you have provided is a perfect Golomb ruler (can measure $n(n-1)$ lengths where $n$ is the number of marks, and in your case is $2\cdot 3=6$). Do you want an algorithm for perfect rulers or for general rulers? Because, if you want the former, then there exist no such rulers with more than 4 marks. — Yuzuriha Inori 23 mins ago
7:45 PM
Alexander, it is ok :). Sometimes the notations are not clear. BTW here is my Qiskit implementation/tutorial for one qubit VQE that might be interesting: github.com/DavitKhach/quantum-algorithms-tutorials/blob/master/… — Davit Khachatryan 38 secs ago
Yeah, i found out about the convention few minutes back. I was testing with |001> and |100> and found it. — Uzumaki Saptarshi 1 min ago
Wow! Thank you. There are probably many ways to answer this question but you somehow nailed it for me with the practical approach — Alexander Soare 19 mins ago
@DavitKhachatryan I'm pretty sure I applied my erroneous thinking in the middle of transcribing it which further reinforced said thinking, lol — Alexander Soare 24 mins ago
8:10 PM
Alexander, yes, I can try to review :). You can contact with me by Twitter or Linkedin (both links are available in my QCSE profile). — Davit Khachatryan 7 mins ago
@DavitKhachatryan wow, I actually have this opened up along with mustythoughts.com, and I'm writing my own framework agnostic tutorial as we speak. I'm actually looking for more seasoned quantum computing practitioners to give it a seal of approval by reviewing it before I publish it. If you'd be interested to do so for me please PM me (maybe this is now inappropriate for SE comments so I'll delete it soon) — Alexander Soare 22 mins ago
8:35 PM
Wow, that's quite involved but will hopefully work :) Why can't I just copy the gates one by one to another circuit, until I reach the measurement? — mavzolej 11 mins ago
9:25 PM
Thanks! I guess I’m looking for the dual problem- given about $n^2$ qubits try to make about $n$ of them $1$, so as to satisfy the Golomb property. — Mark S 6 mins ago
1 hour later…
11:30 PM
I am not sure I get you, although I have a vague idea what you mean. Can you provide a couple of examples to demonstrate your idea? Say with 4 and 9 qubits? — Yuzuriha Inori 21 mins ago
« first day (786 days earlier) ← previous day next day → last day (1442 days later) »