Γ-convergence

In the field of mathematical analysis for the calculus of variations, Γ-convergence (Gamma-convergence) is a notion of convergence for functionals. It was introduced by Ennio De Giorgi.

Definition

Let $X$ be a topological space and ${\mathcal {N}}(x)$ denote the set of all neighbourhoods of the point $x\in X$ . Let further $F_{n}:X\to {\overline {\mathbb {R} }}$ be a sequence of functionals on $X$ . The Γ-lower limit and the Γ-upper limit are defined as follows:

\Gamma {\text{-}}\liminf _{n\to \infty }F_{n}(x)=\sup _{N_{x}\in {\mathcal {N}}(x)}\liminf _{n\to \infty }\inf _{y\in N_{x}}F_{n}(y),

\Gamma {\text{-}}\limsup _{n\to \infty }F_{n}(x)=\sup _{N_{x}\in {\mathcal {N}}(x)}\limsup _{n\to \infty }\inf _{y\in N_{x}}F_{n}(y)

.

$F_{n}$ are said to $\Gamma$ -converge to $F$ , if there exist a functional $F$ such that $\Gamma {\text{-}}\liminf _{n\to \infty }F_{n}=\Gamma {\text{-}}\limsup _{n\to \infty }F_{n}=F$ .

Definition in first-countable spaces

In first-countable spaces, the above definition can be characterized in terms of sequential $\Gamma$ -convergence in the following way. Let $X$ be a first-countable space and $F_{n}:X\to {\overline {\mathbb {R} }}$ a sequence of functionals on $X$ . Then $F_{n}$ are said to $\Gamma$ -converge to the $\Gamma$ -limit $F:X\to {\overline {\mathbb {R} }}$ if the following two conditions hold:

Lower bound inequality: For every sequence $x_{n}\in X$ such that $x_{n}\to x$ as $n\to +\infty$ ,

F(x)\leq \liminf _{n\to \infty }F_{n}(x_{n}).

Upper bound inequality: For every $x\in X$ , there is a sequence $x_{n}$ converging to $x$ such that

F(x)\geq \limsup _{n\to \infty }F_{n}(x_{n})

The first condition means that $F$ provides an asymptotic common lower bound for the $F_{n}$ . The second condition means that this lower bound is optimal.

Relation to Kuratowski convergence

$\Gamma$ -convergence is connected to the notion of Kuratowski-convergence of sets. Let ${\text{epi}}(F)$ denote the epigraph of a function $F$ and let $F_{n}:X\to {\overline {\mathbb {R} }}$ be a sequence of functionals on $X$ . Then

{\text{epi}}(\Gamma {\text{-}}\liminf _{n\to \infty }F_{n})={\text{K}}{\text{-}}\limsup _{n\to \infty }{\text{epi}}(F_{n}),

{\text{epi}}(\Gamma {\text{-}}\limsup _{n\to \infty }F_{n})={\text{K}}{\text{-}}\liminf _{n\to \infty }{\text{epi}}(F_{n}),

where ${\text{K-}}\liminf$ denotes the Kuratowski limes inferior and ${\text{K-}}\limsup$ the Kuratowski limes superior in the product topology of $X\times \mathbb {R}$ . In particular, $(F_{n})_{n}$ $\Gamma$ -converges to $F$ in $X$ if and only if $({\text{epi}}(F_{n}))_{n}$ ${\text{K}}$ -converges to ${\text{epi}}(F)$ in $X\times \mathbb {R}$ . This is the reason why $\Gamma$ -convergence is sometimes called epi-convergence.

Properties

Minimizers converge to minimizers: If $F_{n}$ $\Gamma$ -converge to $F$ , and $x_{n}$ is a minimizer for $F_{n}$ , then every cluster point of the sequence $x_{n}$ is a minimizer of $F$ .
$\Gamma$ -limits are always lower semicontinuous.
$\Gamma$ -convergence is stable under continuous perturbations: If $F_{n}$ $\Gamma$ -converges to $F$ and $G:X\to [0,+\infty )$ is continuous, then $F_{n}+G$ will $\Gamma$ -converge to $F+G$ .
A constant sequence of functionals $F_{n}=F$ does not necessarily $\Gamma$ -converge to $F$ , but to the relaxation of $F$ , the largest lower semicontinuous functional below $F$ .

Applications

An important use for $\Gamma$ -convergence is in homogenization theory. It can also be used to rigorously justify the passage from discrete to continuum theories for materials, for example, in elasticity theory.

References

A. Braides: Γ-convergence for beginners. Oxford University Press, 2002.
G. Dal Maso: An introduction to Γ-convergence. Birkhäuser, Basel 1993.