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In quantum mechanics, a density matrix (or density operator) is a matrix that describes an ensemble [1] of physical systems as quantum states (even if the ensemble contains only one system). It allows for the calculation of the probabilities of the outcomes of any measurements performed upon the systems of the ensemble using the Born rule .
Because Bell states are entangled states, information on the entire system may be known, while withholding information on the individual subsystems. For example, the Bell state is a pure state, but the reduced density operator of the first qubit is a mixed state. The mixed state implies that not all the information on this first qubit is known. [1]
1. A Bell-diagonal state is separable if all the probabilities are less or equal to 1/2, i.e., /. [2]2. Many entanglement measures have a simple formulas for entangled Bell-diagonal states: [1]
The fidelity between two quantum states and , expressed as density matrices, is commonly defined as: [1] [2] (,) = ().The square roots in this expression are well-defined because both and are positive semidefinite matrices, and the square root of a positive semidefinite matrix is defined via the spectral theorem.
The lower bound is obtained by the completely mixed state, represented by the matrix . The purity of a quantum state is conserved under unitary transformations acting on the density matrix in the form †, where U is a unitary matrix.
in which is the reduced density matrix (or its continuous-variable analogue [7]) across the bipartition of the pure state, and it measures how much the complex amplitudes deviate from the constraints required for tensor separability. The faithful nature of the measure admits necessary and sufficient conditions of separability for pure states.
Quantum tomography is applied on a source of systems, to determine the quantum state of the output of that source. Unlike a measurement on a single system, which determines the system's current state after the measurement (in general, the act of making a measurement alters the quantum state), quantum tomography works to determine the state(s) prior to the measurements.
When the sender and receiver share a Bell state, two classical bits can be packed into one qubit. In the diagram, lines carry qubits , while the doubled lines carry classic bits . The variables b 1 and b 2 are classic Boolean, and the zeroes at the left-hand side represent the pure quantum state | 0 {\displaystyle |0\rangle } .