A function calculating the value of expression (sin(x) - x)*x^(-3).

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Mikl Nik
Mikl Nik el 22 de Abr. de 2020
Comentada: David Hill el 24 de Abr. de 2020
write a function (exact specification below) calculating as accurately and as quickly as possible the value of the expression f(x) = (sin(x) - x)*x^(-3).
the maximum absolute error of the results calculated using the sent function should not exceed ≈100ε,
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Mikl Nik
Mikl Nik el 22 de Abr. de 2020
function Y = c4(X)
n = size(X,1) * size(X,2);
Y = zeros(size(X,1), size(X,2));
for i=1:n
Y(i) = -1/6;
k = 1;
while k<200
Y(i) = Y(i) + (-1)^(k+1)*X(i)^(2*k)/factorial(2*k+3);
k = k + 1;
end
end
Well, I use Taylor series to solve this problem and the values of expressions are pretty close, but they are still exceeding 100*eps.
Mikl Nik
Mikl Nik el 22 de Abr. de 2020
And yes, it's an example for controlling the cancellation error for small x.
And as I say, I used Taylor series:
f(x) = -1/6 + x^2/120 - x^4/5040 + x^6/362880 - x^8/39916800 + ...
So with help of while loop I was trying to write Taylor series for N = 200.

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Respuestas (2)

David Hill
David Hill el 22 de Abr. de 2020
x=.5;%whatever
n=200;
f=sum((ones(1,n+1)*x).^(0:2:2*n).*(-1).^(1:n+1)./factorial(2*(0:n)+3));
g=(sin(x)-x)*x^-3;
h=abs(f-g)<10*eps;
James Tursa
James Tursa el 22 de Abr. de 2020
Editada: James Tursa el 23 de Abr. de 2020
So, for small values of x your code looks correct to me (although the N=200 is WAY WAY OVERKILL ... you don't need nearly this many terms). And when you compare it to extended precision from Symbolic Toolbox using vpa( ) this seems to confirm that you nailed it:
>> digits 100 % <-- use 100 digits extended precision
>> c = @(x)(sin(x)-x)/x^3
c =
function_handle with value:
@(x)(sin(x)-x)/x^3
>> c(1e-5)
ans =
-0.166667284899440 % <-- lots of cancellation error in this
>> c4(1e-5)
ans =
-0.166666666665833
>> c4(1e-5) - double(c(vpa(1e-5)))
ans =
0 % <-- compared to extended precision you nailed it down to the last bit
>>
>> c(1e-10)
ans =
0 % <-- MASSIVE cancellation error here ... lost everything
>> c4(1e-10)
ans =
-0.166666666666667
>> c4(1e-10) - double(c(vpa(1e-10)))
ans =
0 % <-- compared to extended precision you nailed it down to the last bit
So, maybe adjust your while loop to end sooner, but your Taylor Series code is correct. E.g., as soon as your terms stop contributing to the sum because they are too small, you can stop the while loop. Consider x = 1e-2. Each term is going to go down by (1e-2)^2/factorial(something) compared to the last term. It only takes a few of these terms before you are beyond 1e-16 or so and they stop contributing to the sum in double precision.
Was there a particular range of inputs that you are interested in? For a generic function you would probably set a threshold of input magnitude for when to calculate the function outright and when to use the Taylor Series.
When you thought you were greater than 100*eps, I think you were incorrectly comparing to the original function as written using a double input instead of comparing to an extended precision routine. As the results show above, not only is your Taylor Series code under 100*eps, it is matching the extended precision calculation down to the last bit. Can't ask for better than that!
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Mikl Nik
Mikl Nik el 24 de Abr. de 2020
Test function shows there results. I've got this test function from my teacher and it divides the run time of my program by the run time of the most effective program.
David Hill
David Hill el 24 de Abr. de 2020
Did you try the above code?

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