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Quellcode-Bibliothek© Kompilation durch diese Firma[Weder Korrektheit noch Funktionsfähigkeit der Software werden zugesichert.]Datei: sortmachine.vdmpp Sprache: PVSOriginal von: PVS© |
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limit_vect2_vect2: THEORY
BEGIN IMPORTING vectors@vect2_fun_ops, reals@abs_lems, analysis@epsilon_lemmas f, f1, f2: VAR [ Vect2 -> Vect2] g : VAR [Vect2 -> nzreal] epsilon, delta : VAR posreal a,x,v: VAR Vect2 l,l1,l2,b,c,y1,y2: VAR Vect2 const_fun(v) : [Vect2 -> Vect2] = LAMBDA x : v ; +(f1, f2) : [Vect2 -> Vect2] = LAMBDA x : f1(x) + f2(x); -(f1) : [Vect2 -> Vect2] = LAMBDA x : -f1(x); -(f1, f2) : [Vect2 -> Vect2] = LAMBDA x : f1(x) - f2(x); %%% *(f1, f2) : [Vect2 -> Vect2] = LAMBDA x : f1(x) * f2(x); %--------------------------------------------------- % Convergence of f at a point a towards a limit l %--------------------------------------------------- convergence(f, a, l) : bool = FORALL epsilon : EXISTS delta : FORALL x: norm(x-a) < delta IMPLIES norm(f(x) - l) < epsilon cv_unique : LEMMA convergence(f, a, l1) AND convergence(f, a, l2) IMPLIES l1 = l2 cv_in_domain : LEMMA convergence(f, x, l) IMPLIES l = f(x) %------------------------------------------- % convergence and operations on functions %------------------------------------------- cv_sum : LEMMA convergence(f1, a, l1) AND convergence(f2, a, l2) IMPLIES convergence(f1 + f2, a, l1 + l2) cv_neg : LEMMA convergence(f, a, l) IMPLIES convergence(- f, a, - l) cv_diff : LEMMA convergence(f1, a, l1) AND convergence(f2, a, l2) IMPLIES convergence(f1 - f2, a, l1 - l2) % cv_prod : LEMMA convergence(f1, a, l1) AND convergence(f2, a, l2) % IMPLIES convergence(f1 * f2, a, l1 * l2) cv_const : LEMMA convergence(const_fun(b), v, b) % cv_scal : LEMMA convergence(f, a, l) % IMPLIES convergence(b * f, a, b * l) %------------------------- % f is convergent at a %------------------------- convergent?(f, a) : bool = EXISTS l : convergence(f, a, l) lim(f, (x0 : {a | convergent?(f, a)})) : Vect2 = choose(LAMBDA l : convergence(f, x0, l)) lim_fun_lemma : LEMMA FORALL f, (x0 : {a | convergent?(f, a)}) : convergence(f, x0, lim(f, x0)) lim_fun_def : LEMMA FORALL f, l, (x0 : {a | convergent?(f, a)}) : lim(f, x0) = l IFF convergence(f, x0, l) convergence_equiv : LEMMA convergence(f, a, l) IFF convergent?(f, a) AND lim(f, a) = l convergent_in_domain : LEMMA convergent?(f, x) IFF convergence(f, x, f(x)) lim_in_domain : LEMMA convergent?(f, x) IMPLIES lim(f, x) = f(x) %------------------------------------------ % Operations preserving convergence at a %------------------------------------------ sum_fun_convergent : LEMMA convergent?(f1, a) AND convergent?(f2, a) IMPLIES convergent?(f1 + f2, a) neg_fun_convergent : LEMMA convergent?(f, a) IMPLIES convergent?(- f, a) diff_fun_convergent : LEMMA convergent?(f1, a) AND convergent?(f2, a) IMPLIES convergent?(f1 - f2, a) % prod_fun_convergent : LEMMA convergent?(f1, a) AND convergent?(f2, a) % IMPLIES convergent?(f1 * f2, a) const_fun_convergent: LEMMA convergent?(const_fun(b), v) % scal_fun_convergent : LEMMA convergent?(f, a) IMPLIES convergent?(b * f, a) %---------------------------- % Same things with lim(a) %---------------------------- lim_sum_fun : LEMMA convergent?(f1, a) AND convergent?(f2, a) IMPLIES lim(f1 + f2, a) = lim(f1, a) + lim(f2, a) lim_neg_fun : LEMMA convergent?(f, a) IMPLIES lim(- f, a) = - lim(f, a) lim_diff_fun : LEMMA convergent?(f1, a) AND convergent?(f2, a) IMPLIES lim(f1 - f2, a) = lim(f1, a) - lim(f2, a) % lim_prod_fun : LEMMA convergent?(f1, a) AND convergent?(f2, a) % IMPLIES lim(f1 * f2, a) = lim(f1, a) * lim(f2, a) lim_const_fun : LEMMA lim(const_fun(b), v) = b % lim_scal_fun : LEMMA convergent?(f, a) % IMPLIES lim(b * f, a) = b * lim(f, a) % %----------------------------- % % Limit preserve order % %----------------------------- % convergence_order : LEMMA % FORALL f1, f2, a, l1, l2 : % convergence(f1, a, l1) % AND convergence(f2, a, l2) % AND (FORALL x : f1(x) <= f2(x)) % IMPLIES l1 <= l2 % %------------------------------------------- % % Bounds on function are bounds on limits % %------------------------------------------- % convergence_lower_bound : COROLLARY % FORALL f, b, a, l : % convergence(f, a, l) % AND (FORALL x : b <= f(x)) % IMPLIES b <= l % convergence_upper_bound : COROLLARY % FORALL f, b, a, l : % convergence(f, a, l) % AND (FORALL x : f(x) <= b) % IMPLIES l <= b % %-------------------- % % Bounds on limits % %-------------------- % lim_le1 : LEMMA % convergent?(f, a) AND (FORALL x : f(x) <= b) IMPLIES lim(f, a) <= b % lim_ge1 : LEMMA % convergent?(f, a) AND (FORALL x : f(x) >= b) IMPLIES lim(f, a) >= b % lim_order1 : LEMMA convergent?(f1, a) AND convergent?(f2, a) % AND (FORALL x : f1(x) <= f2(x)) % IMPLIES lim(f1, a) <= lim(f2, a) END limit_vect2_vect2 ¤ Dauer der Verarbeitung: 0.1 Sekunden (vorverarbeitet) ¤ |
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