Can you explain this in detail\begin{align*} e^{i \sigma_z \otimes \sigma_z t} &= \cos(t) I + i \sin(t) \sigma_z \otimes \sigma_z =\\ &= \mathrm{CNOT} e^{i \sigma_z \otimes I t} \mathrm{CNOT} = \mathrm{CNOT} \left(e^{i \sigma_z t} \otimes I\right) \mathrm{CNOT} \end{align*} — Omkar 18 mins ago
I edited the answer with more detailed explanations. Now I don't have that step, instead, I have 3 steps in my answer. The first step is to describe $e^{i\sigma_z \otimes \sigma_z t}$ by using the Euler-like formula for Pauli matrices. In the second and third steps, I show that the presented circuit is equal to the $e^{i\sigma_z \otimes \sigma_z t}$. Also, I changed/corrected some notations. — Davit Khachatryan2 mins ago
haha, yup, i just mean a walkthrough, as you mentioned. I'm having a little trouble following the provided example, could you help to simply walk through the example i provided? I'm sorry, i'm new to this. — VP919 mins ago
@EmilProdan: Maybe, there is a bug in graph visualization, however, when you look at state vector below graph, Y gate work as expected. — Martin Vesely10 mins ago
Thanks, that could be the right place. It seems that the visualization neglects entirely the minus sign on the imaginary part but not on the real part. For example, 5 T's should produce a phase 5pi/4, but again the color is wrong. 4 T's are fine. — Emil Prodan13 mins ago
Could you clarify what exactly you're having trouble with? I could just paste the walkthrough from my previous answer but if you're finding something specific unclear in it, it will remain unclear :-) Also, you're starting with qubits in |11> before applying the Hadamards, but the typical Deutsch algorithm starts in |01> - could this contribute to your confusion? — Mariia Mykhailova23 mins ago
for sure . . . its just the algebra part, ie how from the ψc⟩=1/2(|0f(0)⟩−|1f(1)⟩−|0f~(0)⟩+|1f~(1)⟩) state can we "pull out" (for example, if f(0)=f(1) ) |ψc⟩=1/2(|0⟩−|1⟩)(|f(0)⟩−|f(0)⟩). .. cause there are only half as many terms. is there cancelling out? — VP923 mins ago