Energetic space

In mathematics, more precisely in functional analysis, an energetic space is, intuitively, a subspace of a given real Hilbert space equipped with a new "energetic" inner product. The motivation for the name comes from physics, as in many physical problems the energy of a system can be expressed in terms of the energetic inner product. An example of this will be given later in the article.

Energetic space[edit]

Formally, consider a real Hilbert space $X$ with the inner product $(\cdot |\cdot )$ and the norm $\|\cdot \|$ . Let $Y$ be a linear subspace of $X$ and $B:Y\to X$ be a strongly monotone symmetric linear operator, that is, a linear operator satisfying

$(Bu|v)=(u|Bv)\,$ for all $u,v$ in $Y$
$(Bu|u)\geq c\|u\|^{2}$ for some constant $c>0$ and all $u$ in $Y.$

The energetic inner product is defined as

(u|v)_{E}=(Bu|v)\,

for all

u,v

in

Y

and the energetic norm is

\|u\|_{E}=(u|u)_{E}^{\frac {1}{2}}\,

for all

u

in

Y.

The set $Y$ together with the energetic inner product is a pre-Hilbert space. The energetic space $X_{E}$ is defined as the completion of $Y$ in the energetic norm. $X_{E}$ can be considered a subset of the original Hilbert space $X,$ since any Cauchy sequence in the energetic norm is also Cauchy in the norm of $X$ (this follows from the strong monotonicity property of $B$ ).

The energetic inner product is extended from $Y$ to $X_{E}$ by

(u|v)_{E}=\lim _{n\to \infty }(u_{n}|v_{n})_{E}

where $(u_{n})$ and $(v_{n})$ are sequences in Y that converge to points in $X_{E}$ in the energetic norm.

Energetic extension[edit]

The operator $B$ admits an energetic extension $B_{E}$

B_{E}:X_{E}\to X_{E}^{*}

defined on $X_{E}$ with values in the dual space $X_{E}^{*}$ that is given by the formula

\langle B_{E}u|v\rangle _{E}=(u|v)_{E}

for all

u,v

in

X_{E}.

Here, $\langle \cdot |\cdot \rangle _{E}$ denotes the duality bracket between $X_{E}^{*}$ and $X_{E},$ so $\langle B_{E}u|v\rangle _{E}$ actually denotes $(B_{E}u)(v).$

If $u$ and $v$ are elements in the original subspace $Y,$ then

\langle B_{E}u|v\rangle _{E}=(u|v)_{E}=(Bu|v)=\langle u|B|v\rangle

by the definition of the energetic inner product. If one views $Bu,$ which is an element in $X,$ as an element in the dual $X^{*}$ via the Riesz representation theorem, then $Bu$ will also be in the dual $X_{E}^{*}$ (by the strong monotonicity property of $B$ ). Via these identifications, it follows from the above formula that $B_{E}u=Bu.$ In different words, the original operator $B:Y\to X$ can be viewed as an operator $B:Y\to X_{E}^{*},$ and then $B_{E}:X_{E}\to X_{E}^{*}$ is simply the function extension of $B$ from $Y$ to $X_{E}.$

An example from physics[edit]

Consider a string whose endpoints are fixed at two points $a<b$ on the real line (here viewed as a horizontal line). Let the vertical outer force density at each point $x$ $(a\leq x\leq b)$ on the string be $f(x)\mathbf {e}$ , where $\mathbf {e}$ is a unit vector pointing vertically and $f:[a,b]\to \mathbb {R} .$ Let $u(x)$ be the deflection of the string at the point $x$ under the influence of the force. Assuming that the deflection is small, the elastic energy of the string is

{\frac {1}{2}}\int _{a}^{b}\!u'(x)^{2}\,dx

and the total potential energy of the string is

F(u)={\frac {1}{2}}\int _{a}^{b}\!u'(x)^{2}\,dx-\int _{a}^{b}\!u(x)f(x)\,dx.

The deflection $u(x)$ minimizing the potential energy will satisfy the differential equation

-u''=f\,

with boundary conditions

u(a)=u(b)=0.\,

To study this equation, consider the space $X=L^{2}(a,b),$ that is, the Lp space of all square-integrable functions $u:[a,b]\to \mathbb {R}$ in respect to the Lebesgue measure. This space is Hilbert in respect to the inner product

(u|v)=\int _{a}^{b}\!u(x)v(x)\,dx,

with the norm being given by

\|u\|={\sqrt {(u|u)}}.

Let $Y$ be the set of all twice continuously differentiable functions $u:[a,b]\to \mathbb {R}$ with the boundary conditions $u(a)=u(b)=0.$ Then $Y$ is a linear subspace of $X.$

Consider the operator $B:Y\to X$ given by the formula

Bu=-u'',\,

so the deflection satisfies the equation $Bu=f.$ Using integration by parts and the boundary conditions, one can see that

(Bu|v)=-\int _{a}^{b}\!u''(x)v(x)\,dx=\int _{a}^{b}u'(x)v'(x)=(u|Bv)

for any $u$ and $v$ in $Y.$ Therefore, $B$ is a symmetric linear operator.

$B$ is also strongly monotone, since, by the Friedrichs's inequality

\|u\|^{2}=\int _{a}^{b}u^{2}(x)\,dx\leq C\int _{a}^{b}u'(x)^{2}\,dx=C\,(Bu|u)

for some $C>0.$

The energetic space in respect to the operator $B$ is then the Sobolev space $H_{0}^{1}(a,b).$ We see that the elastic energy of the string which motivated this study is

{\frac {1}{2}}\int _{a}^{b}\!u'(x)^{2}\,dx={\frac {1}{2}}(u|u)_{E},

so it is half of the energetic inner product of $u$ with itself.

To calculate the deflection $u$ minimizing the total potential energy $F(u)$ of the string, one writes this problem in the form

(u|v)_{E}=(f|v)\,

for all

v

in

X_{E}

.

Next, one usually approximates $u$ by some $u_{h}$ , a function in a finite-dimensional subspace of the true solution space. For example, one might let $u_{h}$ be a continuous piecewise linear function in the energetic space, which gives the finite element method. The approximation $u_{h}$ can be computed by solving a system of linear equations.

The energetic norm turns out to be the natural norm in which to measure the error between $u$ and $u_{h}$ , see Céa's lemma.

References[edit]

Zeidler, Eberhard (1995). Applied functional analysis: applications to mathematical physics. New York: Springer-Verlag. ISBN 0-387-94442-7.

Johnson, Claes (1987). Numerical solution of partial differential equations by the finite element method. Cambridge University Press. ISBN 0-521-34514-6.

Energetic space[edit]

Energetic extension[edit]

An example from physics[edit]

See also[edit]

References[edit]