[HELP] A Classical Numerical Computing Question

1 vue (au cours des 30 derniers jours)
Xiao Tang
Xiao Tang le 8 Sep 2012
f(x) = (exp(x)-1)/x; g(x) = (exp(x)-1)/log(exp(x))
Analytically, f(x) = g(x).
When x is approaching to 0, both f(x) and g(x) are approaching to 1. However, g(x) works better than f(x).
% Compute y against x
for k = 1:15
x(k) = 10^(-k);
f(k) =(exp(x(k))-1)/x(k);
De(k) = log(exp(x(k)));
g(k)= (exp(x(k))-1)/De(k);
end
% Plot y
plot(1:15,f,'r',1:15,g,'b');
f(x) actually diverges when x approaches to 0.But shouldn't them be the same??

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Réponse acceptée

Matt Fig
Matt Fig le 8 Sep 2012
Modifié(e) : Matt Fig le 8 Sep 2012
No, they shouldn't be the same at the fringes. This is an example of why we often have to look for more stable ways of doing in floating point arithmetic what is analytically simple. Look how f oscillates:
f = @(x) (exp(x)-1)./x;
g = @(x) (exp(x)-1)./log(exp(x));
x = 0:1e-13:1e-7; % Try with x = 0:2e-14:1e-7;
ax(1) = subplot(1,2,1);
plot(x,f(x),'r')
title('(exp(x)-1)./x')
ax(2) = subplot(1,2,2);
plot(x,g(x),'b');
title('(exp(x)-1)./log(exp(x))')
L = get(gca,{'xlim','ylim'});
axis(ax(1),[L{:}])
  3 commentaires
Afficher 1 commentaire plus ancien
Matt Fig
Matt Fig le 8 Sep 2012
I think what we have is a case of near perfect cancellation of errors. Take a look:
x = 1e-12:1e-12:1e-9; % Double values
X = vpa(1/10^12:1/10^12:1/10^9,80); % Symbolic values
syms Z
D = abs(X - log(exp(x)));
E = abs(X-x);
plot(D)
figure
plot(E) % Very little difference
F = abs((exp(x)-1) - subs(exp(Z)-1,X));
figure
plot(F) % Notice similarity to D!
G = F-D;
max(double(G)) % Cancellation of errors.
Xiao Tang
Xiao Tang le 9 Sep 2012
Thank you so much!

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