Gâteaux differential

The Gâteaux differential , named after René Gâteaux (1889–1914), represents a generalization of the common notion of differentiation in that it defines the directional derivation also in infinite-dimensional spaces. Usually one has an open set for a function that is differentiable at that point as the definition of the partial derivative ${\ displaystyle f \ colon G \ to \ mathbb {R}, \ G \ subset \ mathbb {R} ^ {n}}$ ${\ displaystyle x_ {0} \ in G}$

{\ displaystyle {\ frac {\ partial f (x_ {0})} {\ partial x_ {i}}} = \ lim _ {h \ to 0} {\ frac {f (x_ {0,1}, x_ {0,2}, \ ldots, x_ {0, i} + h, \ ldots, x_ {0, n}) - f (x_ {0})} {h}}, \ \ (i = {1, 2, ..., n})}

.

In particular, it results for the known differential ${\ displaystyle n = 1}$

{\ displaystyle {\ frac {\ mathrm {d} f (x_ {0})} {\ mathrm {d} x}} = \ lim _ {h \ to 0} {\ frac {f (x_ {0} + h) -f (x_ {0})} {h}}}

.

The Gâteaux differential generalizes these concepts to infinite-dimensional vector spaces.

Definitions

Weierstrasse's decomposition formula

Be with open and standardized spaces. Then in Gâteaux is called-differentiable if the Weierstrasse decomposition formula holds, i.e. if a linear function exists such that ${\ displaystyle f \ colon D \ subset X \ to Y}$ ${\ displaystyle D}$ ${\ displaystyle X, Y}$ ${\ displaystyle f}$ ${\ displaystyle x_ {0} \ in D}$ ${\ displaystyle A \ in L (X, Y)}$

{\ displaystyle \ lim _ {t \ rightarrow 0} {\ frac {1} {t}} [f (x_ {0} + th) -f (x_ {0}) - tAh] = 0}

for everyone with . This is equivalent to: ${\ displaystyle h \ in X}$ ${\ displaystyle \ lVert h \ rVert = 1}$

{\ displaystyle f (x_ {0} + th) -f (x_ {0}) = tAh + o (| t |)}

Then it is called the Gâteaux derivation of in the point . ${\ displaystyle A =: f '(x_ {0})}$ ${\ displaystyle f}$ ${\ displaystyle x_ {0}}$

1. variation; Variation derivative

Let the following situation be given for the Gâteaux differential: Let it be, as usual, a functional defined in; be a linear normed space (that is, a vector space , provided with a norm ) or a more general topological vector space with prerequisites, about which one has to think more closely in the concrete application; further be and . Then the Gâteaux differential is at the point in direction , if it exists, defined by the following derivative : ${\ displaystyle f \ colon D (f) \ to \ mathbb {R}}$ ${\ displaystyle D (f) \ subseteq \ Omega}$ ${\ displaystyle \ Omega}$ ${\ displaystyle \ | \ cdot \ |}$ ${\ displaystyle x_ {0} \ in D (f)}$ ${\ displaystyle v \ in \ Omega}$ ${\ displaystyle x_ {0}}$ ${\ displaystyle v}$ ${\ displaystyle \ epsilon}$

{\ displaystyle \ delta f (x_ {0}, v) = \ lim _ {\ epsilon \ to 0} {\ frac {f (x_ {0} + \ epsilon \ cdot v) -f (x_ {0}) } {\ epsilon}} = \ left. {\ frac {\ mathrm {d} f (x_ {0} + \ epsilon \ cdot v)} {\ mathrm {d} \ epsilon}} \ right | _ {\ epsilon = 0}}

or for by ${\ displaystyle x_ {1} \ in D (f)}$

{\ displaystyle \ delta f (x_ {0}, x_ {1} -x_ {0}) = \ lim _ {\ epsilon \ to 0} {\ frac {f (x_ {0} + \ epsilon \ cdot (x_ {1} -x_ {0})) - f (x_ {0})} {\ epsilon}} \,. \,}

Note here , and also in it, but . ${\ displaystyle x_ {0} \ in D (f)}$ ${\ displaystyle v \ in \ Omega}$ ${\ displaystyle x_ {1} -x_ {0}}$ ${\ displaystyle \ epsilon \ in \ mathbb {R}}$

The Gâteaux derivation according to is a functional with regard to size , which is also referred to as the 1st variation of at this point . ${\ displaystyle \ epsilon}$ ${\ displaystyle h: = x_ {1} -x_ {0}}$ ${\ displaystyle f}$ ${\ displaystyle x_ {0}}$

Another possibility is to use more general topological vector spaces with a corresponding concept of convergence instead of normalized vector spaces . In physics books in particular, functionals are usually denoted by letters , and instead of size one usually writes with distribution-valued quantities. Instead of the derivation , the so-called variation derivation is introduced in an additional step , which is closely related to the Gâteaux derivation. ${\ displaystyle I}$ ${\ displaystyle h: = x_ {1} -x_ {0}}$ ${\ displaystyle \ delta q (x)}$ ${\ displaystyle {\ tfrac {dI (x + \ epsilon \ cdot h)} {d \ epsilon}} _ {\, | \ epsilon = 0}}$

example

For

{\ displaystyle f (\ epsilon): = \ int \, {\ rm {d}} t \, {\ mathcal {L}} \ left (t, q (t) + \ epsilon \ cdot \ delta q (t ), {\ dot {q}} (t) + \ epsilon \ cdot {\ frac {{\ rm {d}} (\ delta q (t))} {{\ rm {d}} t}} \ right )}

after a partial integration with a vanishing, fully integrated part, a result of the form with the derivative of the variation is obtained ${\ displaystyle \ textstyle {\ frac {{\ rm {d}} f} {{\ rm {d}} \ epsilon}} (\ epsilon \ to 0) \, = \, \ int \, {\ rm { d}} t \, {\ frac {\ delta {\ mathcal {L}}} {\ delta q (t)}} \ cdot \ delta q (t)}$

{\ displaystyle {\ frac {\ delta {\ mathcal {L}}} {\ delta q (t)}} \ equiv {\ frac {\ partial {\ mathcal {L}}} {\ partial q (t)} } - {\ frac {\ rm {d}} {{\ rm {d}} t}} {\ frac {\ partial {\ mathcal {L}}} {\ partial {\ dot {q}} (t) }} \ ,.}

(The variation derivative "at point q (t)" for continuous variables is therefore the generalization of the partial derivative of a function from n variables, for example for the fictitious case . Similar to the total differential of a function of n variables in the fictitious case , so here , too , the total differential of the functional has an invariant meaning. Further details in the chapter Lagrange formalism .) ${\ displaystyle {\ tfrac {\ partial {\ mathcal {L}}} {\ partial x_ {i}}}}$ ${\ displaystyle {\ mathcal {L}} = {\ mathcal {L}} (x_ {1}, ..., x_ {n})}$ ${\ displaystyle \ delta f}$

In the following, for the sake of simplicity, the vectors are not identified by "bold" letters.

2nd variation

{\ displaystyle \ delta ^ {2} f (x_ {0}, v) = \ left. {\ frac {\ mathrm {d} ^ {2} f (x_ {0} + \ epsilon \ cdot v)} { \ mathrm {d} \ epsilon ^ {2}}} \ right | _ {\ epsilon = 0}}

Half-sided differential and directional derivative

Under the same conditions as above, the one-sided Gâteaux differential is through

{\ displaystyle \ delta _ {+} f (x_ {0}, v) = \ lim _ {\ epsilon \ to 0 ^ {+}} {\ frac {f (x_ {0} + \ epsilon \ cdot v) -f (x_ {0})} {\ epsilon}}}

respectively through

{\ displaystyle \ delta _ {-} f (x_ {0}, v) = \ lim _ {\ epsilon \ to 0 ^ {-}} {\ frac {f (x_ {0} + \ epsilon \ cdot v) -f (x_ {0})} {\ epsilon}}}

Are defined. The one-sided Gâteaux differential is also called the directional differential of at the point . For the direction belonging to the vector , in the case of “continuous variables”, the one-sided Gâteaux differential (more precisely: the associated variation derivative) just generalizes the directional derivative from in the direction at the point . ${\ displaystyle f}$ ${\ displaystyle x_ {0}}$ ${\ displaystyle v}$ ${\ displaystyle f}$ ${\ displaystyle v}$ ${\ displaystyle x_ {0}}$

Gâteaux derivative

If an in continuous linear functional (i.e. the function mediated by is homogeneous, additive and continuous in the argument ), then it is called Gâteaux-derivative in that place and Gâteaux-differentiable in . ${\ displaystyle \ delta f (x_ {0}, v)}$ ${\ displaystyle v}$ ${\ displaystyle v \ mapsto \ delta f (x_ {0}, v)}$ ${\ displaystyle v}$ ${\ displaystyle f '(x_ {0})}$ ${\ displaystyle x_ {0}}$ ${\ displaystyle f}$ ${\ displaystyle x_ {0}}$

Properties of the 1st variation

The Gâteaux differential is homogeneous, which means for everyone . The same applies to the one-sided Gâteaux differential.
${\ displaystyle \ delta f (x_ {0}, k \ cdot v) = k \ cdot \ delta f (x_ {0}, v)}$
${\ displaystyle k \ in \ mathbb {R}}$

The Gâteaux differential is not linear. In the general case, for an example that the Gâteaux differential is not linear, consider for and , where , then is . The function is not linear. It applies, for example .
${\ displaystyle \ delta f (x_ {0}, v) + \ delta f (x_ {0}, w) \ neq \ delta f (x_ {0}, v + w).}$
${\ displaystyle f (x) = {\ tfrac {x_ {1} ^ {2} x_ {2}} {x_ {1} ^ {2} + x_ {2} ^ {2}}}}$ ${\ displaystyle x \ neq 0}$ ${\ displaystyle f (0) = 0}$ ${\ displaystyle x = (x_ {1}, x_ {2})}$
${\ displaystyle \ delta f (0, v) = \ lim _ {\ epsilon \ to 0} {\ frac {f (0+ \ epsilon \ cdot v) -f (0)} {\ epsilon}} = \ lim _ {\ epsilon \ to 0} {\ frac {f (\ epsilon \ cdot v)} {\ epsilon}} = \ lim _ {\ epsilon \ to 0} {\ frac {\ epsilon ^ {2} v_ {1 } ^ {2} \ cdot \ epsilon v_ {2}} {(\ epsilon ^ {2} v_ {1} ^ {2} + \ epsilon ^ {2} v_ {2} ^ {2}) \ epsilon}} = {\ frac {v_ {1} ^ {2} v_ {2}} {v_ {1} ^ {2} + v_ {2} ^ {2}}} = f (v)}$
${\ displaystyle f}$ ${\ displaystyle \ delta f (0, (0.1)) + \ delta f (0, (1.0)) = 0 + 0 \ neq {\ tfrac {1} {2}} = \ delta f (0 , (1,1))}$

Examples

${\ displaystyle f (x_ {1}, x_ {2}) = 1}$ if , or otherwise . ${\ displaystyle x_ {2} = x_ {1} ^ {2}}$ ${\ displaystyle x_ {1} \ neq 0}$ ${\ displaystyle 0}$ ${\ displaystyle \ delta f ((0,0), v) = \ lim _ {t \ to 0} {\ frac {0-0} {t}} = 0}$
${\ displaystyle f (x) = | x |, \ x \ in \ mathbb {R} ^ {n}}$ ${\ displaystyle \ delta _ {+} f (0, v) = \ lim _ {\ epsilon \ to 0 ^ {+}} {\ frac {| 0+ \ epsilon \ cdot v | -0} {\ epsilon} } = | v |}$
${\ displaystyle f (x_ {1}, x_ {2}) = x_ {1} ^ {2} \ left (1 + {\ frac {1} {x_ {2}}} \ right)}$ for and for , ${\ displaystyle x_ {2} \ neq 0}$ ${\ displaystyle - {\ frac {x_ {1} ^ {2}} {x_ {2} ^ {2}}}}$ ${\ displaystyle x_ {2} = 0}$ ${\ displaystyle \ nabla f (x_ {1}, x_ {2}) = \ left (2 \ cdot x_ {1} \ cdot \ left (1 + {\ frac {1} {x_ {2}}} \ right ), - {\ frac {x_ {1} ^ {2}} {x_ {2} ^ {2}}} \ right) ^ {T}}$

${\ displaystyle \ delta f ((0,0), v) = \ lim _ {\ epsilon \ to 0} {\ frac {(\ epsilon \ cdot v_ {1}) ^ {2} \ cdot \ left (1st + {\ frac {1} {\ epsilon \ cdot v_ {2}}} \ right)} {\ epsilon}} = {\ frac {v_ {1} ^ {2}} {v_ {2}}}}$ (where ) ${\ displaystyle v = (v_ {1}, v_ {2}) ^ {T}}$

Applications

Like the usual derivative , the Gâteaux differential is useful for determining extrema and therefore in optimization . Be open, linear normalized space, (the interior of the set ), and the open ball around with radius . Necessary optimality condition: Let be a local minimum of on , then if the one-sided Gâteaux differential in exists. Sufficient optimality condition: have in a 2nd variation and . If and for one and , then there is a strict local minimum of on . ${\ displaystyle f \ colon X \ to \ mathbb {R}, \ X \ subset D (f) \ subset \ Omega}$ ${\ displaystyle \ Omega}$ ${\ displaystyle x_ {0} \ in \ operatorname {int} (X)}$ ${\ displaystyle X}$ ${\ displaystyle \ operatorname {int} (X) \ neq \ emptyset}$ ${\ displaystyle B _ {\ varepsilon} (x_ {0})}$ ${\ displaystyle x_ {0}}$ ${\ displaystyle \ varepsilon}$ ${\ displaystyle x_ {0}}$ ${\ displaystyle f}$ ${\ displaystyle X}$ ${\ displaystyle \ delta _ {+} f (x_ {0}, v) \ geq 0 \ \ forall v \ in \ Omega}$ ${\ displaystyle x_ {0}}$ ${\ displaystyle f}$ ${\ displaystyle B _ {\ varepsilon} (x_ {0})}$ ${\ displaystyle \ forall v \ in \ Omega}$ ${\ displaystyle \ forall x \ in B _ {\ varepsilon} (x_ {0})}$ ${\ displaystyle \ delta f (x_ {0}, v) = 0 \ \ forall v \ in \ Omega}$ ${\ displaystyle c> 0}$ ${\ displaystyle \ delta ^ {2} f (x_ {0}, v) \ geq c \ cdot \ | v \ | ^ {2} \ \ forall v \ in \ Omega}$ ${\ displaystyle \ forall x \ in B _ {\ varepsilon} (x_ {0})}$ ${\ displaystyle x_ {0}}$ ${\ displaystyle f}$ ${\ displaystyle \ operatorname {int} (X)}$