Linear entropy

This article needs attention from an expert on the subject. Please add a reason or a talk parameter to this template to explain the issue with the article. When placing this tag, consider associating this request with a WikiProject.

This article provides insufficient context for those unfamiliar with the subject. Please help improve the article by providing more context for the reader. (June 2009) (Learn how and when to remove this message)

In quantum mechanics, and especially quantum information theory, the linear entropy of a state is is a scalar defined as

${\displaystyle S_{L}\,{\dot {=}}\,1-{\mbox{Tr}}(\rho ^{2})\,}$

where ${\displaystyle \rho \,}$ is the density matrix of the state. The subscript ${\displaystyle L\,}$ is to distinguish this quantity from the Von Neumann entropy. The linear entropy and Von Neumann entropy are similar measures of the "mixedness" of a state, although the linear entropy is easier to calculate because it does not require the diagonalization of the density matrix.

The linear entropy can range between zero, corresponding to a completely pure state, and ${\displaystyle 1-1/d\,}$, corresponding to a completely mixed state. (Here, ${\displaystyle d\,}$ is the dimension of the density matrix.)

Linear entropy is trivially related to the purity ${\displaystyle \gamma \,}$ of a state by

${\displaystyle S_{L}\,=\,1-\gamma \,.}$

Some authors^[1]define linear entropy with a different normalization

${\displaystyle S_{L}\,{\dot {=}}\,{\frac {d}{d-1}}(1-{\mbox{Tr}}(\rho ^{2}))\,.}$

This ensures that the quantity ranges from zero to unity.

This quantum mechanics-related article is a stub. You can help Wikipedia by expanding it.

• v
• t
• e