The conditional quantum entropy is an

entropy measure Entropy is a Science, scientific concept, most commonly associated with states of disorder, randomness, or uncertainty. The term and the concept are used in diverse fields, from classical thermodynamics, where it was first recognized, to th ...

used in

quantum information theory Quantum information is the information of the state of a quantum system. It is the basic entity of study in quantum information theory, and can be manipulated using quantum information processing techniques. Quantum information refers to both t ...

. It is a generalization of the

conditional entropy In information theory, the conditional entropy quantifies the amount of information needed to describe the outcome of a random variable Y given that the value of another random variable X is known. Here, information is measured in shannons, n ...

of classical information theory. For a bipartite state

\rho^

, the conditional entropy is written

S(A, B)_\rho

, or

H(A, B)_\rho

, depending on the notation being used for the

von Neumann entropy In physics, the von Neumann entropy, named after John von Neumann, is a measure of the statistical uncertainty within a description of a quantum system. It extends the concept of Gibbs entropy from classical statistical mechanics to quantum statis ...

. The quantum conditional entropy was defined in terms of a conditional density operator

\rho_

by Nicolas Cerf and Chris Adami, who showed that quantum conditional entropies can be negative, something that is forbidden in classical physics. The negativity of quantum conditional entropy is a sufficient criterion for quantum non-separability. In what follows, we use the notation

S(\cdot)

for the

, which will simply be called "entropy".

Definition

Given a bipartite quantum state

\rho^

, the entropy of the joint system AB is

S(AB)_\rho \ \stackrel\   S(\rho^)

, and the entropies of the subsystems are

S(A)_\rho \ \stackrel\   S(\rho^A) = S(\mathrm_B\rho^)

and

S(B)_\rho

. The von Neumann entropy measures an observer's uncertainty about the value of the state, that is, how much the state is a mixed state. By analogy with the classical conditional entropy, one defines the conditional quantum entropy as

S(A, B)_\rho \ \stackrel\  S(AB)_\rho - S(B)_\rho

. An equivalent operational definition of the quantum conditional entropy (as a measure of the

quantum communication In quantum information theory, a quantum channel is a communication channel that can transmit quantum information, as well as classical information. An example of quantum information is the general dynamics of a qubit. An example of classical in ...

cost or surplus when performing

quantum state In quantum physics, a quantum state is a mathematical entity that embodies the knowledge of a quantum system. Quantum mechanics specifies the construction, evolution, and measurement of a quantum state. The result is a prediction for the system ...

merging) was given by

Michał Horodecki Michał Horodecki (born 1973) is a Polish physicist at the University of Gdańsk working in the field of quantum information theory, notable for his work on entanglement theory. He co-discovered the Peres-Horodecki criterion for testing whether ...

, Jonathan Oppenheim, and Andreas Winter.

Properties

Unlike the classical

, the conditional quantum entropy can be negative. This is true even though the (quantum) von Neumann entropy of single variable is never negative. The negative conditional entropy is also known as the coherent information, and gives the additional number of bits above the classical limit that can be transmitted in a quantum dense coding protocol. Positive conditional entropy of a state thus means the state cannot reach even the classical limit, while the negative conditional entropy provides for additional information.

References

* *{{citation, first=Mark M., last=Wilde, arxiv=1106.1445, title=Quantum Information Theory, pages=xi-xii, year=2017, publisher=Cambridge University Press, bibcode = 2011arXiv1106.1445W , doi=10.1017/9781316809976.001, chapter=Preface to the Second Edition, isbn=9781316809976, s2cid=2515538 Quantum mechanical entropy