Hello. Feigenbaum delta from the logistic map. Been stuck for hours and i dont know how to solve it. Please tell me my mistake and if its completly wrong please tell me
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THE QUESTION
Compute the Feigenbaum delta from the logistic map. The logistic map is given by
,
and the Feigenbaum delta is defined as
where
and where is the value of μ for which is in the orbit of the period-N cycle with .
Here is a resonable outline:
Loop 1 Start at period- with , and increment n with each iteration
Compute initial guess for using , and .
Loop 2 Iterate Newton's method, either a fixed number of times or until convergence
Initialize logistic map
Loop 3 Iterate the logistic map times
Compute x and
Loop 3 (end)
One step of Newton's method
Loop 2 (end)
Save and compute
Loop 1 (end)
Grading will be done on the converged values of up to . Set .
clc
clear all;
start_time = clock;
a0 = 2; a1 = 1+ sqrt(5); d=4;
mu(1)=a0;
mu(2)=a1;
for k = 3:15
a = a1 + (al-a0)/d;
for i = 1:2
res = 0.5; der = 0;
for j = 2:2^(k-1)+1
der = res*(1-res)+ a*(1-2*res)*der;
end
a= a-(res-0.5)/der;
end
%d = (a1-a0)/(a-a1); % approxima
fins a 4.66919841237705
d = (vpa(a1)-vpa(a0))/(vpa(a)-vpa(a1));
% approxima a 4.69201587522386
que, s clarament
millor
fprintf('Approximaci n mero % us %.15f/n', k,double(d));
a0 = a1,
a1 = a;
mu(k)=a;
end
end_time= clock;
total_time= end_time-start_time
2 Comments
Dyuman Joshi
on 22 Jan 2024
What is the expected output from the question?
Is it a script-based problem or a function-based problem?
Also, some pointers for the code -
> You don't need to use vpa() here, so remove it.
However, is it necessary to calculate the time taken by the code in the question?
Answers (1)
Vinayak
on 19 Jan 2024
Hi,
After analysing your code and the required map, I found a few issues. It is my understanding that you are referring to variable ‘a1’ instead of ‘al’ inside the for loop. I have modified the calculation of “d” according to the equation shared. Here is the updated code:
clc
clear all;
start_time = clock;
a0 = 2; a1 = 1 + sqrt(5); d = 4;
mu = zeros(1, 15); % Initialize mu array
mu(1) = a0;
mu(2) = a1;
for k = 3:15
a = a1 + (a1 - a0) / d;
for i = 1:2
res = 0.5; der = 0;
for j = 2:2^(k - 1) + 1
der = res * (1 - res) + a * (1 - 2 * res) * der;
end
a = a - (res - 0.5) / der;
end
% Corrected indexing for mu array
d = (mu(k-1) - mu(k-2)) / (mu(k) - mu(k-1));
fprintf('Approximation number %d is %.15f\n', k, double(d));
a0 = a1;
a1 = a;
mu(k) = a;
end
end_time = clock;
total_time = etime(end_time, start_time);
fprintf('Total time: %f seconds\n', total_time);
The above updated code correctly computes the Feigenbaum delta from the logistic map.
Hope this helps!
3 Comments
Dyuman Joshi
on 22 Jan 2024
@food lover, There is no "num_doublings" parameter in the answer above, nor is there a for loop with n as the loop index.
Unless we know what code you have provided as the solution and what exactly is the question asking, it is difficult to provide any suggestions.
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