Chapter 2: Classical methods                                      195

                7.2.5   Fields theories
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                                                  N
                                                                  N
                Exercise 2.6.1. Let f ∈ C 2  [a, b] × R × R N  , α, β ∈ R . Assume that there
                            ¡         ¢
                exists Φ ∈ C 3  [a, b] × R N  satisfying Φ (a, α)= Φ (b, β). Suppose also that
                             f (x, u, ξ)= f (x, u, ξ)+ hΦ u (x, u); ξi + Φ x (x, u)
                             e
                is such that (u, ξ) → f (x, u, ξ) is convex. The claim is then that any solution u
                                  e
                of the Euler-Lagrange system
                                d £          ¤
                                           0             0
                                     (x, u, u ) = f u i  (x, u, u ) ,i =1, ..., N
                                   f ξ i
                               dx
                is a minimizer of
                                     (                             )
                                             Z  b
                                                           0
                            (P)   inf  I (u)=    f (x, u (x) ,u (x)) dx  = m
                                 u∈X           a
                          ©     1  ¡     N  ¢                 ª
                where X = u ∈ C   [a, b]; R  : u (a)= α, u (b)= β .
                The proof is exactly as the one dimensional one and we skip the details.
                Exercise 2.6.2. The procedure is very similar to the one of Theorem 2.27. An
                exact field Φ = Φ (x, u) covering a domain D ⊂ R N+1  is a map Φ : D → R N  so
                                            ¢
                                     ¡
                that there exists S ∈ C 1  D; R N  satisfying
                                           (x, u, Φ (x, u)) ,i =1, ..., N
                           S u i  (x, u)= f ξ i
                           S x (x, u)= f (x, u, Φ (x, u)) − hS u (x, u); Φ (x, u)i .
                                                           N
                The Weierstrass function is defined, for u, η, ξ ∈ R ,as
                        E (x, u, η, ξ)= f (x, u, ξ) − f (x, u, η) − hf ξ (x, u, η);(ξ − η)i .
                The proof is then identical to the one dimensional case.
                Exercise 2.6.3. (i) Wehavebydefinition
                          ⎧
                          ⎨ S u (x, u)= f ξ (x, u, Φ (x, u))

                          ⎩
                             S x (x, u)= − [S u (x, u) Φ (x, u) − f (x, u, Φ (x, u))] .
                We therefore have immediately from Lemma 2.8
                                    S x (x, u)= −H (x, u, S u (x, u)) .

                   (ii) Using again Lemma 2.8 we obtain
                           ⎧
                           ⎨ H (x, u, S u )= S u (x, u) Φ (x, u) − f (x, u, Φ (x, u))

                              S u (x, u)= f ξ (x, u, Φ (x, u)) .
                           ⎩
                Since S is a solution of Hamilton-Jacobi equation, we get S x = −H (x, u, S u ) as
                wished.