I've been working on speeding up the following function, but with no results:
function beta = beta_c(k,c,gamma) beta = zeros(size(k)); E = @(x) (1.453*x.^4)./((1 + x.^2).^(17/6)); for ii = 1:size(k,1) for jj = 1:size(k,2) E_int = integral(E,k(ii,jj),10000); beta(ii,jj) = c*gamma/(k(ii,jj)*sqrt(E_int)); end end end
Up to now, I solved it this way:
function beta = beta_calc(k,c,gamma) k_1d = reshape(k,[1,numel(k)]); E_1d =@(k) 1.453.*k.^4./((1 + k.^2).^(17/6)); E_int = zeros(1,numel(k_1d)); parfor ii = 1:numel(k_1d) E_int(ii) = quad(E_1d,k_1d(ii),10000); end beta_1d = c*gamma./(k_1d.*sqrt(E_int)); beta = reshape(beta_1d,[size(k,1),size(k,2)]); end
Seems to me, it didn't really enhance performances. What do you think about this?
Would you mind to shed a light?
I thank you in advance.
I am gonna introduce some theoretical background involving my question. Generally, beta is to be calculated as follows
Therefore, in the reduced case of unidimensional k array, E_int may be calculated as
E = 1.453.*k.^4./((1 + k.^2).^(17/6)); E_int = 1.5 - cumtrapz(k,E);
or, alternatively as
E_int(1) = 1.5; for jj = 2:numel(k) E =@(k) 1.453.*k.^4./((1 + k.^2).^(17/6)); E_int(jj) = E_int(jj - 1) - integral(E,k(jj-1),k(jj)); end
k is currently a matrix