Unitary Evolution and Elements of Reality in Consecutive Quantum Measurements

Abstract: Probabilities of the outcomes of consecutive quantum measurements can be obtained by construction probability amplitudes, thus implying the unitary evolution of the measured system, broken each time a measurement is made. In practice, the experimenter needs to know all past outcomes at the end of the experiment, and that requires the presence of probes carrying the corresponding records. With this in mind, we consider two different ways to extend the description of a quantum system beyond what is actually meas… Show more

“…Or one can simply say that Alice needs to know matrix elements of a unitary operator $$\hat{U}^{S+P}(t_2,t_0)$$ between particular states in the Hilbert space of the composite, and not mention the evolution at all. [ 27 ]…”

“…Furthermore, the probabilities in Equation (4) can be obtained without mentioning the probes explicitly, since the couplings (Equations (2) and (3)) are simple, and their actions are easily taken into account (details can be found, e.g., in ref. [27]). In particular, one has for the probability of measuring the sequence ($$B_m$$, $$C_n$$), provided the first detection gave $$A_k$$, an equally valid form, $$$$\begin{eqnarray} P(C_n\leftarrow B_m\leftarrow A_k) =|{\langle }c_n| \hat{U}^S(t_2,t_1)\hat{\pi }(B_m)\hat{U}^S(t_1,t_0)|a_k{\rangle }|^2 \end{eqnarray}$$$$if the measured eigenvalue of $$\hat{C}$$ is not degenerate.…”

“…Or one can simply say that Alice needs to know matrix elements of a unitary operator ÛS+P (t 2 , t 0 ) between particular states in the Hilbert space of the composite, and not mention the evolution at all. [27] Furthermore, the probabilities in Equation ( 4) can be obtained without mentioning the probes explicitly, since the couplings (Equations ( 2) and ( 3)) are simple, and their actions are easily taken into account (details can be found, e.g., in ref. [27]).…”

“…[27] Furthermore, the probabilities in Equation ( 4) can be obtained without mentioning the probes explicitly, since the couplings (Equations ( 2) and ( 3)) are simple, and their actions are easily taken into account (details can be found, e.g., in ref. [27]). In particular, one has for the probability of measuring the sequence (B m , C n ), provided the first detection gave A k , an equally valid form,…”

Speakable and Unspeakable in Quantum Measurements

“…Or one can simply say that Alice needs to know matrix elements of a unitary operator $$\hat{U}^{S+P}(t_2,t_0)$$ between particular states in the Hilbert space of the composite, and not mention the evolution at all. [ 27 ]…”

“…Furthermore, the probabilities in Equation (4) can be obtained without mentioning the probes explicitly, since the couplings (Equations (2) and (3)) are simple, and their actions are easily taken into account (details can be found, e.g., in ref. [27]). In particular, one has for the probability of measuring the sequence ($$B_m$$, $$C_n$$), provided the first detection gave $$A_k$$, an equally valid form, $$$$\begin{eqnarray} P(C_n\leftarrow B_m\leftarrow A_k) =|{\langle }c_n| \hat{U}^S(t_2,t_1)\hat{\pi }(B_m)\hat{U}^S(t_1,t_0)|a_k{\rangle }|^2 \end{eqnarray}$$$$if the measured eigenvalue of $$\hat{C}$$ is not degenerate.…”

“…Or one can simply say that Alice needs to know matrix elements of a unitary operator ÛS+P (t 2 , t 0 ) between particular states in the Hilbert space of the composite, and not mention the evolution at all. [27] Furthermore, the probabilities in Equation ( 4) can be obtained without mentioning the probes explicitly, since the couplings (Equations ( 2) and ( 3)) are simple, and their actions are easily taken into account (details can be found, e.g., in ref. [27]).…”

“…[27] Furthermore, the probabilities in Equation ( 4) can be obtained without mentioning the probes explicitly, since the couplings (Equations ( 2) and ( 3)) are simple, and their actions are easily taken into account (details can be found, e.g., in ref. [27]). In particular, one has for the probability of measuring the sequence (B m , C n ), provided the first detection gave A k , an equally valid form,…”

Speakable and Unspeakable in Quantum Measurements