Gibbs' inequality

Last updated April 12, 2024

In information theory, Gibbs' inequality is a statement about the information entropy of a discrete probability distribution. Several other bounds on the entropy of probability distributions are derived from Gibbs' inequality, including Fano's inequality. It was first presented by J. Willard Gibbs in the 19th century.

Gibbs' inequality

Suppose that $P=\{p_{1},\ldots ,p_{n}\}$ and $Q=\{q_{1},\ldots ,q_{n}\}$ are discrete probability distributions. Then

-\sum _{i=1}^{n}p_{i}\log p_{i}\leq -\sum _{i=1}^{n}p_{i}\log q_{i}

with equality if and only if $p_{i}=q_{i}$ for $i=1,\dots n$ .^[1]^: 68 Put in words, the information entropy of a distribution $P$ is less than or equal to its cross entropy with any other distribution $Q$ .

The difference between the two quantities is the Kullback–Leibler divergence or relative entropy, so the inequality can also be written:^[2]^: 34

D_{\mathrm {KL} }(P\|Q)\equiv \sum _{i=1}^{n}p_{i}\log {\frac {p_{i}}{q_{i}}}\geq 0.

Note that the use of base-2 logarithms is optional, and allows one to refer to the quantity on each side of the inequality as an "average surprisal" measured in bits.

Proof

For simplicity, we prove the statement using the natural logarithm, denoted by $ln$ , since

\log _{b}a={\frac {\ln a}{\ln b}},

so the particular logarithm base $b > 1$ that we choose only scales the relationship by the factor $1 / ln b$ .

Let $I$ denote the set of all $i$ for which p_i is non-zero. Then, since $\ln x\leq x-1$ for all x > 0, with equality if and only if x=1, we have:

-\sum _{i\in I}p_{i}\ln {\frac {q_{i}}{p_{i}}}\geq -\sum _{i\in I}p_{i}\left({\frac {q_{i}}{p_{i}}}-1\right)

=-\sum _{i\in I}q_{i}+\sum _{i\in I}p_{i}=-\sum _{i\in I}q_{i}+1\geq 0

The last inequality is a consequence of the p_i and q_i being part of a probability distribution. Specifically, the sum of all non-zero values is 1. Some non-zero q_i, however, may have been excluded since the choice of indices is conditioned upon the p_i being non-zero. Therefore, the sum of the q_i may be less than 1.

So far, over the index set $I$ , we have:

-\sum _{i\in I}p_{i}\ln {\frac {q_{i}}{p_{i}}}\geq 0

,

or equivalently

-\sum _{i\in I}p_{i}\ln q_{i}\geq -\sum _{i\in I}p_{i}\ln p_{i}

.

Both sums can be extended to all $i=1,\ldots ,n$ , i.e. including $p_{i}=0$ , by recalling that the expression $p\ln p$ tends to 0 as $p$ tends to 0, and $(-\ln q)$ tends to $\infty$ as $q$ tends to 0. We arrive at

-\sum _{i=1}^{n}p_{i}\ln q_{i}\geq -\sum _{i=1}^{n}p_{i}\ln p_{i}

For equality to hold, we require

${\frac {q_{i}}{p_{i}}}=1$ for all $i\in I$ so that the equality $\ln {\frac {q_{i}}{p_{i}}}={\frac {q_{i}}{p_{i}}}-1$ holds,
and $\sum _{i\in I}q_{i}=1$ which means $q_{i}=0$ if $i\notin I$ , that is, $q_{i}=0$ if $p_{i}=0$ .

This can happen if and only if $p_{i}=q_{i}$ for $i=1,\ldots ,n$ .

Alternative proofs

The result can alternatively be proved using Jensen's inequality, the log sum inequality, or the fact that the Kullback-Leibler divergence is a form of Bregman divergence. Below we give a proof based on Jensen's inequality:

Because log is a concave function, we have that:

\sum _{i}p_{i}\log {\frac {q_{i}}{p_{i}}}\leq \log \sum _{i}p_{i}{\frac {q_{i}}{p_{i}}}=\log \sum _{i}q_{i}\leq 0

Where the first inequality is due to Jensen's inequality, and the last equality is due to the same reason given in the above proof.

Furthermore, since $\log$ is strictly concave, by the equality condition of Jensen's inequality we get equality when

{\frac {q_{1}}{p_{1}}}={\frac {q_{2}}{p_{2}}}=\cdots ={\frac {q_{n}}{p_{n}}}

and

\sum _{i}q_{i}=1

Suppose that this ratio is $\sigma$ , then we have that

1=\sum _{i}q_{i}=\sum _{i}\sigma p_{i}=\sigma

Where we use the fact that $p,q$ are probability distributions. Therefore, the equality happens when $p=q$ .

Corollary

The entropy of $P$ is bounded by:^[1]^: 68

H(p_{1},\ldots ,p_{n})\leq \log n.

The proof is trivial – simply set $q_{i}=1/n$ for all i.

Related Research Articles

In information theory, the entropy of a random variable is the average level of "information", "surprise", or "uncertainty" inherent to the variable's possible outcomes. Given a discrete random variable $, which takes values in the alphabet and is distributed according to, the entropy is$

The principle of maximum entropy states that the probability distribution which best represents the current state of knowledge about a system is the one with largest entropy, in the context of precisely stated prior data.

In information theory, the asymptotic equipartition property (AEP) is a general property of the output samples of a stochastic source. It is fundamental to the concept of typical set used in theories of data compression.

The sum of the reciprocals of all prime numbers diverges; that is:

<span class="mw-page-title-main">Gumbel distribution</span> Particular case of the generalized extreme value distribution

In probability theory and statistics, the Gumbel distribution is used to model the distribution of the maximum of a number of samples of various distributions.

<span class="mw-page-title-main">Jensen's inequality</span> Theorem of convex functions

In mathematics, Jensen's inequality, named after the Danish mathematician Johan Jensen, relates the value of a convex function of an integral to the integral of the convex function. It was proved by Jensen in 1906, building on an earlier proof of the same inequality for doubly-differentiable functions by Otto Hölder in 1889. Given its generality, the inequality appears in many forms depending on the context, some of which are presented below. In its simplest form the inequality states that the convex transformation of a mean is less than or equal to the mean applied after convex transformation; it is a simple corollary that the opposite is true of concave transformations.

In probability theory, a Chernoff bound is an exponentially decreasing upper bound on the tail of a random variable based on its moment generating function. The minimum of all such exponential bounds forms the Chernoff or Chernoff-Cramér bound, which may decay faster than exponential. It is especially useful for sums of independent random variables, such as sums of Bernoulli random variables.

In quantum mechanics, information theory, and Fourier analysis, the entropic uncertainty or Hirschman uncertainty is defined as the sum of the temporal and spectral Shannon entropies. It turns out that Heisenberg's uncertainty principle can be expressed as a lower bound on the sum of these entropies. This is stronger than the usual statement of the uncertainty principle in terms of the product of standard deviations.

In mathematical statistics, the Kullback–Leibler (KL) divergence, denoted $, is a type of statistical distance: a measure of how one probability distribution P is different from a second, reference probability distribution Q . A simple interpretation of the KL divergence of P from Q is the expected excess surprise from using Q as a model when the actual distribution is P . While it is a measure of how different two distributions are, and in some sense is thus a "distance", it is not actually a metric, which is the most familiar and formal type of distance. In particular, it is not symmetric in the two distributions, and does not satisfy the triangle inequality. Instead, in terms of information geometry, it is a type of divergence, a generalization of squared distance, and for certain classes of distributions, it satisfies a generalized Pythagorean theorem.$

In information theory, the Rényi entropy is a quantity that generalizes various notions of entropy, including Hartley entropy, Shannon entropy, collision entropy, and min-entropy. The Rényi entropy is named after Alfréd Rényi, who looked for the most general way to quantify information while preserving additivity for independent events. In the context of fractal dimension estimation, the Rényi entropy forms the basis of the concept of generalized dimensions.

In information theory, the cross-entropy between two probability distributions $and over the same underlying set of events measures the average number of bits needed to identify an event drawn from the set if a coding scheme used for the set is optimized for an estimated probability distribution, rather than the true distribution .$

In statistics and information theory, a maximum entropy probability distribution has entropy that is at least as great as that of all other members of a specified class of probability distributions. According to the principle of maximum entropy, if nothing is known about a distribution except that it belongs to a certain class, then the distribution with the largest entropy should be chosen as the least-informative default. The motivation is twofold: first, maximizing entropy minimizes the amount of prior information built into the distribution; second, many physical systems tend to move towards maximal entropy configurations over time.

The Theil index is a statistic primarily used to measure economic inequality and other economic phenomena, though it has also been used to measure racial segregation.

Differential entropy is a concept in information theory that began as an attempt by Claude Shannon to extend the idea of (Shannon) entropy, a measure of average (surprisal) of a random variable, to continuous probability distributions. Unfortunately, Shannon did not derive this formula, and rather just assumed it was the correct continuous analogue of discrete entropy, but it is not. The actual continuous version of discrete entropy is the limiting density of discrete points (LDDP). Differential entropy is commonly encountered in the literature, but it is a limiting case of the LDDP, and one that loses its fundamental association with discrete entropy.

In probability theory and statistics, the Jensen–Shannon divergence is a method of measuring the similarity between two probability distributions. It is also known as information radius (IRad) or total divergence to the average. It is based on the Kullback–Leibler divergence, with some notable differences, including that it is symmetric and it always has a finite value. The square root of the Jensen–Shannon divergence is a metric often referred to as Jensen–Shannon distance.

In quantum information theory, quantum relative entropy is a measure of distinguishability between two quantum states. It is the quantum mechanical analog of relative entropy.

Inequalities are very important in the study of information theory. There are a number of different contexts in which these inequalities appear.

In information theory, Pinsker's inequality, named after its inventor Mark Semenovich Pinsker, is an inequality that bounds the total variation distance in terms of the Kullback–Leibler divergence. The inequality is tight up to constant factors.

In probability theory, a subgaussian distribution, the distribution of a subgaussian random variable, is a probability distribution with strong tail decay. More specifically, the tails of a subgaussian distribution are dominated by the tails of a Gaussian. This property gives subgaussian distributions their name.

<span class="mw-page-title-main">Young's inequality for products</span> Mathematical concept

In mathematics, Young's inequality for products is a mathematical inequality about the product of two numbers. The inequality is named after William Henry Young and should not be confused with Young's convolution inequality.

References

1 2 Pierre Bremaud (6 December 2012). An Introduction to Probabilistic Modeling. Springer Science & Business Media. ISBN 978-1-4612-1046-7.
↑ David J. C. MacKay (25 September 2003). Information Theory, Inference and Learning Algorithms. Cambridge University Press. ISBN 978-0-521-64298-9.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Bremaud2012-1] 1 2 Pierre Bremaud (6 December 2012). An Introduction to Probabilistic Modeling. Springer Science & Business Media. ISBN 978-1-4612-1046-7.

[MacKay2003-2] David J. C. MacKay (25 September 2003). Information Theory, Inference and Learning Algorithms. Cambridge University Press. ISBN 978-0-521-64298-9.

[1]

[2]

Gibbs' inequality

Contents