6:15 AM
@Henry_Fordham: I am not expert on physical design, so I cannot give you answer. However, the original question was about simulators. — Martin Vesely 1 min ago
3 hours later…
8:45 AM
#2: In the specific case where you know that one of the states is decohered, things can simplify a bit (for example, in the original question). What is the difference between a dephased state and one with off-diagonal elements? This is what is called quantum coherence. Given a fixed basis (for example, the $\sigma_{z}$ basis for a single qubit), all states that are diagonal in this basis are called ``incoherent'' states, while those that are not diagonal are called coherent states. — keisuke.akira 1 min ago
#1: I'll give two answers: the general way to distinguish two states and the specific case where one of them is decohered. In the most general case, one would need to do quantum state tomography -- that is, measure the state in many different bases and then (experimentally) reconstruct the states to find that they are indeed different. For example, given two qubit states $\rho, \sigma$, to distinguish them, you'd need to measure them in the bases $\sigma_{x}, \sigma_{y}, \sigma_{z}$ and then you can distinguish any two different states. — keisuke.akira 4 mins ago
9:10 AM
Also, @MusashiK, if you're satisfied with this answer then please accept it. — keisuke.akira 6 mins ago
Also, in response to @QurakNerd's comment: yes, you can experimentally measure $\mathrm{Tr}(\rho^2)$, which is called the purity of a quantum state. However, purity cannot always distinguish a dephased state from a state with non-zero off-diagonal terms -- in general, one would need to make measurements, etc., along the lines of my comment above. — keisuke.akira 21 mins ago
#4: These two bases should, in general, be sufficient to distinguish a dephased state from a non-dephased one (as an example, in the original question, we have that the $\sigma_{z}$ and $\sigma_{x}$ eigenbases are mutually unbiased and we use the Hadamard operator to go from one to the other). You're welcome to ask more specific questions if you'd like :) — keisuke.akira 22 mins ago
#3: Note that, since density matrices are hermitian, every density matrix is diagonal in some basis -- but the question here is, whether, given a fixed basis, some state is diagonal in this basis or not. Then, one can either compute various coherence measures (like relative entropy of coherence) on these states and then distinguish them. Or, for a more experimental approach, one can measure them in the diagonal basis and a basis which is mutually unbiased with respect to it. — keisuke.akira 24 mins ago
5 hours later…
2:35 PM
m1, m2, mk? they are density matrices, so they do. how do i improve my answer? — Hasan Iqbal 1 min ago
3 hours later…
5:30 PM
Thank you and Have accepted the answer. Was not aware of this action - as this was my 1-st question. — MusashiK 34 secs ago
5:55 PM
It would be sufficient to show that $ker(T)\subseteq ket(T^C)$ where $T$ is your channel and $T^C$ is its complementary channel, both of which do have have nice formulas in terms of the Kraus operators for $T$. Though I am not sure how you could get a handle on characterizing the operators in the kernel of $T$... this (older) paper is a good starting point arxiv.org/pdf/0802.1360.pdf not sure what is state of the art these days though. — Connor 10 mins ago
2 hours later…
8:00 PM
@keisuke.akira The path of knowledge to measuring and quantifying coherence indicated in answer 2 is enlightening and wide. — MusashiK 10 secs ago
2 hours later…
10:05 PM
Well, if $m_1$, $m_2$, and $m_k$ all have trace 1, then $m_1 + m_k$ and $m_2 + m_k$ certainly do not, which makes fidelities involving them somewhat less meaningful. — Niel de Beaudrap 11 mins ago
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