How to integrate using while loop?

조회 수: 9 (최근 30일)
Andrejus
Andrejus 2014년 10월 21일
댓글: Torsten 2017년 1월 3일
Hi all,
I have a function: PM =@(w) (5/16*3^2.*(0.5578^4./w.^5).*exp(-5/4.*(w./0.5578).^(-4)));
its integral: A=integral(PM, 0, 5);
I want to divide the area under the function into equal area pieces. Each beeing of a size= A/n, where n is any number desired. To achieve this I was trying to use while loop, but did not succed. Additionally, I need to keep trace at which values of w the condtion is met.
Thanks.

이 질문에 답변하려면 로그인하십시오.

채택된 답변

Mike Hosea
Mike Hosea 2014년 10월 21일
편집: Mike Hosea 2014년 10월 21일
I'm assuming this is homework. Let me give you a couple of hints.
1. You can make a function like this
q = @(b)integral(PM,0,b);
Then, as you know,
A = q(5)
But you can make a useful function like this
g = @(b)q(b) - A/5
This function g is zero when integral(PM,0,b) is 1/5 of integral(PM,0,5). Then you might want to look at
g = @(b)q(b) - (2/5)*A.
That function is zero when integral(PM,0,b) = (2/5)*A. And so forth...
2. FZERO is a function that might interest you.
  댓글 수: 3
이전 댓글 1개 표시
Mike Hosea
Mike Hosea 2014년 10월 22일
편집: Mike Hosea 2014년 10월 22일
It works fine in a loop. I just did it and calculated 100 points for exp(-x.*x) over the interval [0,10]. You can use a while loop, but then you have to increment the index variable yourself. It is easier to use a for loop on k = 1:n-1. Then the k-th w value is given by
g = @(w)q(w) - k*(A/n)
w(k) = fzero(g,[1e-10,5]);
I had to use 1e-10 instead of 0 for a left bound because your integrand blows up there. If you want to get fancy, you can use the previously found w value for the lower bound given to fzero instead of 1e-10.
The only reason I can see for using a while loop in particular is if you were going to implement the root-finding algorithm yourself, say using bisection.
Andrejus
Andrejus 2014년 10월 23일
편집: Andrejus 2014년 10월 23일
Yey it works just as I wanted. Thank you very much!

댓글을 달려면 로그인하십시오.

추가 답변 (3개)

Roger Stafford
Roger Stafford 2014년 10월 21일
Actually, Andrejus, if you make a change of variable from w to x according to:
w = x^(-1/4),
you will see that your problem is suddenly converted into a much simpler problem that requires neither numerical integration nor the use of 'fzero'. Ordinary calculus will do the job.
  댓글 수: 3
이전 댓글 1개 표시
Roger Stafford
Roger Stafford 2014년 10월 22일
If the symbolic toolbox's 'int' is applied to the given function, the result is a simple analytic function. In attempting to divide this up into n equal parts the transformation w = x^(-1/4) would almost surely be found to be useful, so one way or another that transformation is begging to be performed, even if the approach is purely by way of Matlab.
Mike Hosea
Mike Hosea 2014년 10월 22일
Let me say at the outset that you're probably right that this is a calculus homework exercise and not a MATLAB programming homework exercise. As a numerical analyst whose use of MATLAB goes back to the FORTRAN version, I do marvel that the Symbolic Toolbox is considered "purely MATLAB" around here. Whether it is or isn't is semantics. When I say "MATLAB", however, it means numerical. I've engineered plenty of test cases for numerical algorithms starting from a solution and then working "backwards" to arrive at a test problem. It's a way of engineering problems that I have an exact answer to for comparison purposes.

댓글을 달려면 로그인하십시오.

Roger Stafford
Roger Stafford 2014년 10월 22일
In order to show that your problem need not involve time-consuming iterative methods here is the complete solution in four lines:
k1 = 5/16*3^2*(0.5578)^4;
k2 = 5/4*(0.5578)^4;
A = k1/k2/4*exp(-k2/5^4); % The total integral (area)
w = (1/5^4-log((1:n)'/n)/k2).^(-1/4); % Upper edges of equal area intervals
The justification of this code comes 1) from using 'int' (or ordinary calculus) to establish that the integral from 0 to t of k1/x^5*exp(-k2/x^4) is simply
k1/k2/4*exp(-k2/t^4)
and 2) that the solution to choosing intervals that divide this into n equal parts, that is, the w(m) such that
m/n = (k1/k2/4*exp(-k2/w(m)^4))/(k1/k2/4*exp(-k2/5^4))
is
w(m) = (1/5^4-log(m/n)/k2).^(-1/4)
by using either 'solve' or ordinary algebra.
  댓글 수: 1
Andrejus
Andrejus 2014년 10월 23일
Thank you for you attempt to help me out. I am sure that your approach is just as good as Mike's but this time I could get his idea faster. Thank you once again!

댓글을 달려면 로그인하십시오.

Roger Stafford
Roger Stafford 2014년 10월 24일
Strictly speaking, this is an answer to a question you haven't asked, Andrejus, but I thought you might be interested in the fact that your request "to divide the area under the function into equal area pieces" is almost the equivalent of asking to fill the space below the curve with random points uniformly distributed area-wise (in a statistical sense.) Because the inverse of the integral of your function is easy to solve for, this can be done with the following code, which is almost identical to the solution I gave earlier to your original request. Ignoring the y values, this is also the solution to generating a random variable, x, whose probability density function (pdf) is the integrand you gave (after being normalized by being divided by the total area.)
k1 = 5/16*3^2*(0.5578)^4; % = 0.27227425026348
k2 = 5/4*(0.5578)^4; % = 0.12101077789488
n = 5000;
x = (1/5^4-log(rand(n,1))/k2).^(-1/4); % <-- The random (x,y) points
y = k1./x.^5.*exp(-k2./x.^4).*rand(n,1);
X = linspace(1e-10,5,500); % <-- The (X,Y) points in the curve above
Y = k1./X.^5.*exp(-k2./X.^4);
plot(X,Y,'r-',x,y,'y.')
  댓글 수: 2
Bambang Dewandaru
Bambang Dewandaru 2017년 1월 3일
I tried to follow your step but even at this stage I did get my function work. Please help. function [ A, PM] = bd(k) a=1; PM= @(w) (a/pi*sin(w*pi/a)+w) A=@(k)integral(PM,0,k);
end
Torsten
Torsten 2017년 1월 3일
A=integral(PM,0,k)
instead of
A=@(k)integral(PM,0,k)
Best wishes
Torsten.

댓글을 달려면 로그인하십시오.

카테고리

Help CenterFile Exchange에서 Logical에 대해 자세히 알아보기

태그

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by