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In probability theory, an ergodic dynamical system is one that, broadly speaking, has the same behavior averaged over time as averaged over the space of all the system's states in its phase space. In physics the term implies that a system satisfies the ergodic hypothesis of thermodynamics.

A random process is ergodic if its time average is the same as its average over the probability space, known in the field of thermodynamics as its ensemble average. The state of an ergodic process after a long time is nearly independent of its initial state.^[1]

The term "ergodic" was derived from the Greek words έργον (ergon: "work") and οδός (odos: "path", "way"). It was chosen by Ludwig Boltzmann while he was working on a problem in statistical mechanics.^[2] The branch of mathematics that studies ergodic systems is known as ergodic theory.

Let ${\displaystyle (X,\;\Sigma ,\;\mu \,)}$ be a probability space, and ${\displaystyle T:X\to X}$ be a measure-preserving transformation. We say that T is ergodic with respect to ${\displaystyle \mu }$ (or alternatively that ${\displaystyle \mu }$ is ergodic with respect to T) if the following equivalent conditions hold:^[3]

• for every ${\displaystyle E\in \Sigma }$ with ${\displaystyle T^{-1}(E)=E\,}$ either ${\displaystyle \mu (E)=0\,}$ or ${\displaystyle \mu (E)=1\,}$;
• for every ${\displaystyle E\in \Sigma }$ with ${\displaystyle \mu (T^{-1}(E)\bigtriangleup E)=0}$ we have ${\displaystyle \mu (E)=0}$ or ${\displaystyle \mu (E)=1\,}$ (where ${\displaystyle \bigtriangleup }$ denotes the symmetric difference);
• for every ${\displaystyle E\in \Sigma }$ with positive measure we have ${\displaystyle \mu \left(\bigcup _{n=1}^{\infty }T^{-n}E\right)=1}$;
• for every two sets E and H of positive measure, there exists an n > 0 such that ${\displaystyle \mu ((T^{-n}E)\cap H)>0}$;
• Every measurable function ${\displaystyle f:X\to \mathbb {R} }$ with ${\displaystyle f\circ T=f}$ is almost surely constant.

These definitions have natural analogues for the case of measurable flows and, more generally, measure-preserving semigroup actions. Let {T^t} be a measurable flow on (X, Σ, μ). An element A of Σ is invariant mod 0 under {T^t} if

${\displaystyle \mu (T^{t}(A)\bigtriangleup A)=0}$

for each t ∈ R. Measurable sets invariant mod 0 under a flow or a semigroup action form the invariant subalgebra of Σ, and the corresponding measure-preserving dynamical system is ergodic if the invariant subalgebra is the trivial σ-algebra consisting of the sets of measure 0 and their complements in X.

A discrete dynamical system ${\displaystyle (X,T)}$, where ${\displaystyle X}$ is a topological space and ${\displaystyle T}$ a continuous map, is said to be uniquely ergodic if there exists a unique ${\displaystyle T}$-invariant Borel probability measure on ${\displaystyle X}$. The invariant measure is then necessary ergodic for ${\displaystyle T}$ (otherwise it could be decomposed as a barycenter of two invariant probability measures with disjoint support).

In a Markov chain with a finite state space, a state ${\displaystyle i}$ is said to be ergodic if it is aperiodic and positive-recurrent (a state is recurrent if there is a nonzero probability of exiting the state, and the probability of an eventual return to it is 1; if the former condition is not true, then the state is "absorbing"). If all states in a Markov chain are ergodic, then the chain is said to be ergodic.

Markov's theorem: a Markov chain is ergodic if there is a positive probability to pass from any state to any other state in one step.

For a Markov chain, a simple test for ergodicity is using eigenvalues of its transition matrix. The number 1 is always an eigenvalue. If all other eigenvalues are positive and less than 1, then the Markov chain is ergodic. This follows from the spectral decomposition of a non-symmetric matrix.

Ergodicity means the ensemble average equals the time average. Following are examples to illustrate that principle.

Each person in a call centre spends time alternately speaking and listening on the telephone, as well as taking breaks between calls. Each break and each call are of different length, as are the durations of each 'burst' of speaking and listening, and indeed so is the rapidity of speech at any given moment, which could each be modelled as random processes. Take N call centre operators (N should be a very large integer) and plot the number of words spoken per minute for those operators for a long period (several shifts). For each person you will have a series of points, which could be joined with lines to create a 'waveform'. Calculate the average value of those points in the waveform; this gives you the time average. Note also that you have N waveforms as we have N operators. These N plots are known as an ensemble. Now take a particular instant of time in all those plots and find the average value of the number of words spoken per minute. That gives you the ensemble average for each plot. If ensemble average and time average are the same then it is ergodic.

Each resistor has an associated thermal noise that depends on the temperature. Take N resistors (N should be very large) and plot the voltage across those resistors for a long period. For each resistor you will have a waveform. Calculate the average value of that waveform; this gives you the time average. Note also that you have N waveforms as we have N resistors. These N plots are known as an ensemble. Now take a particular instant of time in all those plots and find the average value of the voltage. That gives you the ensemble average for each plot. If ensemble average and time average are the same then it is ergodic.

Conceptually, ergodicity of a dynamical system is a certain irreducibility property, akin to the notions of irreducibility in the theory of Markov chains, irreducible representation in algebra and prime number in arithmetic. A general measure-preserving transformation or flow on a Lebesgue space admits a canonical decomposition into its ergodic components, each of which is ergodic.

• Ergodic theory
• Mixing (mathematics)

• Walters, Peter (1982). An Introduction to Ergodic Theory. Springer. ISBN 0-387-95152-0.
• Brin, Michael; Garrett, Stuck (2002). Introduction to Dynamical Systems. Cambridge University Press. ISBN 0-521-80841-3.
• Birkhoff, George D. (December 1931). "Proof of the ergodic theorem" (PDF). Proceedings of the National Academy of Sciences of the United States of America. 17 (12): 656. doi:10.1073/pnas.17.2.656. JSTOR 86016. PMC 1076138. PMID 16577406.
• Alaoglu, Leonidas; Birkhoff, Garrett (April 1940). "General ergodic theorems". The Annals of Mathematics. 2. 41 (2): 293–309. doi:10.2307/1969004. JSTOR 1969004. MR 0002026. PMC 1077986.
• Alaoglu, Leonidas; Birkhoff, Garrett (December 1939). "General ergodic theorems" (PDF). Proceedings of the National Academy of Sciences of the United States of America. 25 (12): 628–630. doi:10.1073/pnas.25.12.628. JSTOR 87048. PMC 1077986. PMID 16588311.

Look up ergodic in Wiktionary, the free dictionary.

• Steven Arthur Kalikow, "Outline of Ergodic Theory"
• Karma Dajani and Sjoerd Dirksin, "A Simple Introduction to Ergodic Theory"