98                                                      Direct methods

                       Exercise 3.4.2 Let
                                                        1   p
                                             f (x, u, ξ)=  |ξ| + g (x, u) .
                                                        p
                       Find growth conditions (depending on p and n)on g that improve (H3) and still
                       allow to derive, as in the preceding exercise, (E w ).

                                                         2
                       Exercise 3.4.3 Let n =2, Ω =(0,π) , u = u (x, t), u t = ∂u/∂t, u x = ∂u/∂x
                       and
                                      ½         ZZ                            ¾
                                               1    ¡  2   2  ¢          1,2
                              (P)  inf I (u)=        u − u x  dx dt : u ∈ W 0  (Ω)  = m.
                                                      t
                                               2   Ω
                          (i) Show that m = −∞.
                          (ii) Prove, formally, that the Euler-Lagrange equation associated to (P) is
                       thewaveequation u tt − u xx =0.


                       3.5    The vectorial case

                       The problem under consideration is
                                 ½       Z                                          ¾
                         (P)  inf I (u)=    f (x, u (x) , ∇u (x)) dx : u ∈ u 0 + W 1,p  ¡ Ω; R N  ¢  = m
                                                                           0
                                          Ω
                       where n, N > 1 and

                                 n
                          - Ω ⊂ R is a bounded open set;
                                    N
                          - f : Ω × R × R N×n  −→ R, f = f (x, u, ξ);
                                                   ³ ´ 1≤j≤N                   ³   ´ 1≤j≤N
                               ¡  1    N  ¢  N       j           N×n            ∂u j
                          - u = u , ..., u  ∈ R , ξ = ξ i     ∈ R    and ∇u =             ;
                                                       1≤i≤n                    ∂x i  1≤i≤n
                                         ¡
                                               ¢
                                                                j
                                                             j
                          - u ∈ u 0 + W  1,p  Ω; R N  means that u ,u ∈ W 1,p  (Ω), j =1, ..., N,and
                                      0                         0
                                 1,p  ¡  N  ¢
                       u − u 0 ∈ W   Ω; R   (which roughly means that u = u 0 on ∂Ω).
                                 0
                          All the results of the preceding sections apply to the present context when
                       n, N > 1.However, while for N =1 (or analogously when n =1) Theorem 3.3
                       was almost optimal, it is now far from being so. The vectorial case is intrinsically
                       more difficult. For example the Euler-Lagrange equations associated to (P) are
                       then a system of partial differential equations, whose treatment is considerably
                       harder than that of a single partial differential equation.
                          We will present one extension of Theorem 3.3; it will not be the best possible
                       result, but it has the advantage of giving some flavours of what can be done. For
                       the sake of clarity we will essentially consider only the case n = N =2; but we
                       will, in a remark, briefly mention what can be done in the higher dimensional
                       case.