@psitae - See my extended answer. — Greg Kuperberg 24 mins ago

MatthewStypulkoski - Yes I understand that, Like I mentioned I was able to work out the errors (only because I have installed Qiskit earlier) but someone starting up afresh will find it difficult and hence was wondering what's the best way to handle this! Just as @met927 pointed to the documentation where it says Python 3.5 or later, and Issues with python 3.8 makes the documentation look silly (given that 3.8 is later version than 3.5) And hence I was hoping to make this information dynamic on documentation somehow! just don't know how can I achieve that and hence I seek help! — aman kumar 17 mins ago

Very weird! I am unable to recreate this. Could you attach a screenshot so I can see what you are experiencing? — met927 3 mins ago

We are looking into this. — Paul Nation 10 mins ago

Thank you so much!! — Shivang Srivastava 1 min ago

this matrix is not diagonal though.. — glS 2 mins ago

Great, thank you very much. I did not realize that +00:00 implies UTC. — Firepanda 5 mins ago

Just hint: first q-bit of result is logical product (AND) of both input q-bits, second one is logical sum (OR) of both inputs. AND and OR can be implemented with Toffoli gate. — Martin Vesely 17 mins ago

This is great, thanks a lot. It wil take me some time to digest all of it though. In the first paragraph, this is the kind of operation that you are talking about, correct? Then I can see how the probabilities become nonuniform after projection, also visualisable like this. Still, this is not just a projection on the z axis, is it? You also need to square the value of $y$. Is $dz/\pi\sqrt{1-z^2}$ the density for the projection or for the probability? — glS 9 mins ago

Hi peachnuts, welcome to QCSE! This may depend on how the quantum bits (qubits) are implemented, but remember a quantum circuit does not generally abstractly describe physical gates, like transistors; rather they are implemented more often as well-timed laser pulses/microwave pulses acting on the qubits. For example, Google's paper on their Sycamore processor - which uses superconducting transmon qubits - goes to some length describing how their gates are implemented with microwave pulses on their qubits. — Mark S 24 mins ago

Two small remarks on the formula for $\rho$: (1) I am using the Hermitian version of the operator $Y = \sigma_y$, i.e., a Pauli spin matrix. (2) As already mentioned in the rebit case, for pure states $\rho = |\psi\rangle\langle\psi|$. These are the states that lie on the Bloch sphere surface. — Greg Kuperberg 16 mins ago

@glS That is what I am talking about, and it is exactly the correct picture for the case of a qubit. The map to the probabilities is quadratic as a map from vector states, but it is linear as a map from operator states. The space of operator states is where the Bloch sphere lives. The map from the Bloch sphere to the classical state on an interval is projection onto the $z$ axis. Work in the usual basis $\rho = (xX + yY + zZ + I)/2$ and you will see it. — Greg Kuperberg 20 mins ago

The use of "unreversible" and "ununitary" in your question is unusual. All operations on a quantum circuit must be unitary, and therefore reversible. — ChainedSymmetry 20 mins ago

Daniel, I agree with @ChainedSymmetry - the question seems confusing. Do you have a classical circuit, and you are wondering how to realize it with quantum (unitary and reversible) gates? A classical circuit made of $\mathsf{AND}$ and $\mathsf{OR}$ gates, such as any bit of combinatorial logic, may be converted to a unitary, reversible circuit that uses Toffoli gates, as Martin mentions. — Mark S 4 mins ago

Mark S is completely right, but if you're looking to build physical intuition you may want to start with something more elementary than transmons, which make use of cQED. If you're looking to ease into things, I went through an implementation of a controlled-not gate based on non-linear optics in this answer, which is about as simple as quantum gates get. — ChainedSymmetry 18 mins ago

@ChainedSymmetry: It bring to my mind one question: What about reset gate? Naturaly, it is not reversible operation. How does this fit to the concept of quantum computation? — Martin Vesely 20 mins ago

I'm afraid this is currently too broad to write a definitive complete answer to, as quite simply, it depends on both the gate and the implementation details, of which there are many - if you have a specific physical type of quantum computer in mind (e.g. superconducting transmons), if you edit the question to include this info, it can get reopened — Mithrandir24601 ♦ 11 mins ago