Can someone look over my newton's method script and see if it looks ok?

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Pam
Pam on 19 Nov 2014
Commented: Pam on 20 Nov 2014
for F(X)=x^3-2x and F'(x)=3x^2-2 with initial guess of x=1
if true
% code
endx = 1;
Tol = 0.0000001;
count = 0;
dx=1;
f=-1;
fprintf('step x dx f(x)\n')
fprintf('---- ----------- --------- ----------\n')
fprintf('%3i %12.8f %12.8f %12.8f\n',count,x,dx,f)
xVec=x;fVec=f;
while (dx > Tol || abs(f)>Tol)
count = count + 1;
fprime = 3*x^2 - 2;
xnew = x - (f/fprime);
dx=abs(x-xnew);
x = xnew;
f = x^3 - 2*x;
fprintf('%3i %12.8f %12.8f %12.8f\n',count,x,dx,f)
end

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Accepted Answer

John D'Errico
John D'Errico on 19 Nov 2014
Edited: John D'Errico on 19 Nov 2014
Several obvious things.
First of all, you never evaluate f to start the method out. Yes, since you know the function f AND the starting value, f(1) = -1, so your code looks like it will work since you hard coded f initially as -1, but it is poor coding style anyway.
Second, I strongly suggest you learn not to hard code in your functions, like f(x) and f'(x). Learn to set up such a function up front, so you could use your code to solve a more general problem. For example, you could set up function handles up front...
f_x = @(x) x.^3 - 2*x;
fp_x = @(x) 3*x.^2 - 2;
I'd also suggest putting in a test for a MaxFunEvals or MaxIterations to prevent some problems. You also use the same Tol parameter for both a test on dx and on abs(f). While that might work on some problems, it is a bad idea in general.
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John D'Errico
John D'Errico on 19 Nov 2014
Edited: John D'Errico on 20 Nov 2014
It looks like you missed one other thing to make it work. You never defined an initial value for x. Ah, but as I write this, you have defined a variable endx, which I realize is a paste issue.
With that, I ran your code. The function you have has several roots. We can solve for them using roots, a numerical solver...
roots([1 0 -2 0])
ans =
0
1.4142
-1.4142
Or the symbolic way, as...
syms x
solve(x^3 - 2*x)
ans =
0
2^(1/2)
-2^(1/2)
In either case, the roots are 0 and +/-sqrt(2).
Running your Newton's method code, it yields a nice approximation to sqrt(2), one of the roots. As expected, it is quadratically convergent near the solution.
step x dx f(x)
---- ----------- --------- ----------
0 1.00000000 1.00000000 -1.00000000
1 2.00000000 1.00000000 4.00000000
2 1.60000000 0.40000000 0.89600000
3 1.44225352 0.15774648 0.11551761
4 1.41501064 0.02724288 0.00319099
5 1.41421424 0.00079640 0.00000269
6 1.41421356 0.00000067 0.00000000
7 1.41421356 0.00000000 0.00000000
So your code worked sucessfully as is.

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