@doc doc""" Tester l'algorithme de Newton local # Entrées : * afficher : (Bool) affichage ou non des résultats de chaque test # Les cas de test (dans l'ordre) * fct 1 : x011,x012 * fct 2 : x021,x022 """ function tester_algo_newton(afficher::Bool, Algorithme_De_Newton::Function) max_iter = 100 Tol_abs = sqrt(eps()) Tol_rel = 1e-15 options = [max_iter, Tol_abs, Tol_rel] @testset "L'algo de Newton" begin @testset "Cas test 1 x0 = solution" begin # point de départ x011 x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct1, grad_fct1, hess_fct1, sol_exacte_fct1, options) if (afficher) afficher_resultats("algorithme de Newton ", "fct1", "x011", x_min, fx_min, flag, sol_exacte_fct1, nb_iters) end @testset "solution" begin @test isapprox(x_min, sol_exacte_fct1, atol = tol_erreur) end @testset "itération" begin @test nb_iters == 0 end end @testset "Cas test 1 x0 = x011" begin #point de départ x011 x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct1, grad_fct1, hess_fct1, pts1.x011, options) if (afficher) afficher_resultats("algorithme de Newton ", "fct1", "x011", x_min, fx_min, flag, sol_exacte_fct1, nb_iters) end @testset "solution" begin @test isapprox(x_min, sol_exacte_fct1, atol = tol_erreur) end @testset "itération" begin @test nb_iters == 1 end end @testset "Cas test 1 x0 = x012" begin x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct1, grad_fct1, hess_fct1, pts1.x012, options) if (afficher) afficher_resultats("algorithme de Newton ", "fct1", "x012", x_min, fx_min, flag, sol_exacte_fct1, nb_iters) end @testset "solution" begin @test x_min ≈ sol_exacte_fct1 atol = tol_erreur end @testset "itération" begin @test nb_iters == 1 end end @testset "Cas test 2 x0 = solution" begin x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct1, grad_fct1, hess_fct1, sol_exacte_fct1, options) if (afficher) afficher_resultats("algorithme de Newton ", "fct1", "x011", x_min, fx_min, flag, sol_exacte_fct1, nb_iters) end @testset "solution" begin @test isapprox(x_min, sol_exacte_fct1, atol = tol_erreur) end @testset "itération" begin @test nb_iters == 0 end end @testset "Cas test 2 x0 = x021" begin x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct2, grad_fct2, hess_fct2, pts1.x021, options) if (afficher) afficher_resultats("algorithme de Newton ", "fct2", "x021", x_min, fx_min, flag, sol_exacte_fct2, nb_iters) end @testset "solution" begin @test x_min ≈ sol_exacte_fct2 atol = tol_erreur end @testset "itération" begin @test nb_iters == 6 end end @testset "Cas test 2 x0 = x022" begin x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct2, grad_fct2, hess_fct2, pts1.x022, options) if (afficher) afficher_resultats("algorithme de Newton ", "fct2", "x022", x_min, fx_min, flag, sol_exacte_fct2, nb_iters) end @testset "solution" begin @test x_min ≈ sol_exacte_fct2 atol = tol_erreur end @testset "itération" begin @test nb_iters == 5 end end @testset "Cas test 2 x0 = x023" begin options[1] = 1 sol = [-4.99999958629818e9, 8.673617379884035e-19] x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct2, grad_fct2, hess_fct2, pts1.x023, options) if (afficher) afficher_resultats("algorithme de Newton ", "fct2", "x022", x_min, fx_min, flag, sol_exacte_fct2, nb_iters) end @testset "solution" begin @test x_min ≈ sol atol = tol_erreur end @testset "exception" begin options[1] = 100 @test_throws SingularException x_min, fx_min, flag, nb_iters = Algorithme_De_Newton(fct2, grad_fct2, hess_fct2, pts1.x023, options) end end end end