Second form of the Euler-Lagrange equation                         59

                                      ©      1                        ª
                Exercise 2.2.9 Let X = u ∈ C ([0, 1]) : u (0) = 0,u (1) = 1 and
                                         ½       Z  1         ¾
                                (P)   inf  I (u)=    |u (x)| dx  = m.
                                                      0
                                      u∈X
                                                   0
                Show that (P) has infinitely many solutions.
                                                   0
                Exercise 2.2.10 Let p ≥ 1 and a ∈ C (R),with a (u) ≥ a 0 > 0.Let A be
                defined by
                                                       1/p
                                          A (u)= [a (u)]  .
                                            0
                Show that a minimizer (which is unique if p> 1)of
                                        (                           )
                                                Z
                                                  b
                                                                p
                              (P)   inf  I (u)=    a (u (x)) |u (x)| dx
                                                            0
                                    u∈X
                                                 a
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                                1
                where X = u ∈ C ([a, b]) : u (a)= α, u (b)= β is given by
                                         ∙                          ¸
                                          A (β) − A (α)
                                       −1
                              u (x)= A                 (x − a)+ A (α) .
                                              b − a
                2.3    Second form of the Euler-Lagrange equation
                The next theorem gives a different way of expressing the Euler-Lagrange equa-
                tion, this new equation is sometimes called DuBois-Reymond equation.It turns
                out to be useful when f does not depend explicitly on x, as already seen in some
                of the above examples.
                                      2
                Theorem 2.7 Let f ∈ C ([a, b] × R × R), f = f (x, u, ξ),and
                                     (                             )
                                             Z  b
                                                           0
                            (P)   inf  I (u)=   f (x, u (x) ,u (x)) dx  = m
                                 u∈X          a
                          ©                               ª
                                                                          2
                                1
                where X = u ∈ C ([a, b]) : u (a)= α, u (b)= β .Let u ∈ X ∩ C ([a, b]) be a
                minimizer of (P) then for every x ∈ [a, b] the following equation holds
                  d
                                                       0
                                                                          0
                               0
                    [f (x, u (x) ,u (x)) − u (x) f ξ (x, u (x) ,u (x))] = f x (x, u (x) ,u (x)) . (2.3)
                                       0
                 dx
                   Proof. We will give two different proofs of the theorem. The first one is
                very elementary and uses the Euler-Lagrange equation . The second one is more
                involved but has several advantages that we do not discuss now.