taylor series method expansion

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PJS KUMAR am 22 Sep. 2018

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https://de.mathworks.com/matlabcentral/answers/420289-taylor-series-method-expansion

Kommentiert: Torsten am 27 Sep. 2018

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I wrote the following code

function yb=taylor(f,a,b,ya,n)
syms x y;
h=(b-a)/n;
y(1)=ya;
y(2)=f;
ht=h.^(0:5)./factorial(0:5)
for i=2:3
      y(i+1)=diff(y(i),x);
end
y

I got the output as follows

>> f=@(x)x^2+y^2;
>> taylor(f,0,0.8,1.5,4)
ht =
    1.0000    0.2000    0.0200    0.0013    0.0001    0.0000
y =
[ 3/2, x^2 + y(x)^2, 2*x + 2*y(x)*diff(y(x), x), 2*diff(y(x), x)^2 + 2*y(x)*diff(y(x), x, x) + 2]

Suggest me how to perform the following actions

1) I want to evaluate y at different values of x

2) Multiply ht and y elements and sum

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PJS KUMAR am 25 Sep. 2018

Bearbeitet: PJS KUMAR am 25 Sep. 2018

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I wrote the following code for Taylor series expansion

function yb=taylor(f,a,b,ya,n)
syms x y;
h=(b-a)/n;
y(1)=ya;
y(2)=f;
ht=h.^(0:3)./factorial(0:3)
for i=2:3
      y(i+1)=diff(y(i),x);
end
s=sum(ht.*y)

I run code and got the following output

>> syms x y(x);
>> f=@(x)x^2+y^2;
>> taylor(f,1,3,0.8,4)
s =
x/4 + (y(x)*diff(y(x), x))/4 + diff(y(x), x)^2/24 + y(x)^2/2 + (y(x)*diff(y(x), x, x))/24 + x^2/2 + 101/120

Now i want to evaluate the output 's' at different values of x and y, where x is from a to b and y(a)=0.8

Walter Roberson am 25 Sep. 2018

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y' = x^2+y^2, for the values of x = 1 (0.5) 3 with y(1)=0.8

I am having difficulty understanding the initial conditions. Could you confirm that you are referring to

syms y(x)
>> simplify(dsolve(diff(y,x) == x^2+y^2, y(1)==0.8))
ans =
piecewise(C5 ~= 0, (x*(4*besselj(-1/4, 1/2)*besselj(-3/4, x^2/2) + 4*besselj(1/4, 1/2)*besselj(3/4, x^2/2) + 5*besselj(-3/4, 1/2)*besselj(3/4, x^2/2) - 5*besselj(3/4, 1/2)*besselj(-3/4, x^2/2)))/(4*besselj(1/4, 1/2)*besselj(-1/4, x^2/2) - 4*besselj(-1/4, 1/2)*besselj(1/4, x^2/2) + 5*besselj(-3/4, 1/2)*besselj(-1/4, x^2/2) + 5*besselj(3/4, 1/2)*besselj(1/4, x^2/2)))

and you want taylor expansion of that without having solved the differential equation ?

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PJS KUMAR am 25 Sep. 2018

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function D = dy(x,y)
  f = x^2+y^2;
  df = 2*x+2*y*f;
  d2f = 2+2*(f^2+y*df);
  d3f = 2*(2*f*df+f*df+y*d2f);
  d4f = 2*(2*(df^2+f*d2f)+df^2+f*d2f+f*d2f+y*d3f);
  D = [f df d2f d3f d4f];
end

suggest me to change the above code as given below, so that the differentiation is calculated by using diff function, without giving the differentiation directly in the program.

function D = dy(x,y)
  f = x^2+y^2;
  df = diff(f);
  d2f = diff(df);
  ---
  ---

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PJS KUMAR am 25 Sep. 2018

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I wrote the program as below

function main
 x = linspace(1,3,5);
 % y = zeros(numel(x));
 h = x(2)-x(1);
 y(1) = 0.8;
 for i = 1:numel(x)-1
   D = dy(x(i),y(i));
    y(i+1) = y(i)+h*D(1)+h^2/2*D(2)+h^3/6*D(3)+h^4/24*D(4)+h^5/120*D(5);
 end
[x' y'] 
end
function D = dy(xnum,ynum)
  syms x y(x)
  f = x^2+y^2;
  df = diff(f,x);
  d2f = diff(df,x);
  d3f = diff(d2f,x);
  d4f = diff(d3f,x);
  fnum = double(subs(f,[x,y],[xnum,ynum]));
  dfnum = double(subs(df,[x,y],[xnum,ynum]));
  d2fnum = double(subs(d2f,[x,y],[xnum,ynum]));
  d3fnum = double(subs(d3f,[x,y],[xnum,ynum]));
  d4fnum = double(subs(d4f,[x,y],[xnum,ynum]));
  D = [fnum,dfnum,d2fnum,d3fnum,d4fnum];
end

It is giving error as

>> main
Index exceeds matrix dimensions.
Error in sym/subs>normalize (line 193)
        Y{i} = fun2sym(Y{i},argnames(X{i}));
Error in sym/subs>mupadsubs (line 147)
[X2,Y2,symX,symY] = normalize(X,Y); %#ok
Error in sym/subs (line 135)
    G = mupadsubs(F,X,Y);
Error in main>dy (line 20)
  fnum = double(subs(f,[x,y],[xnum,ynum]));
Error in main (line 7)
   D = dy(x(i),y(i));

kindly correct the program

Walter Roberson am 26 Sep. 2018

As I tried to get you to understand before:

If you are using a symbolic variable with a particular name, then you should strongly avoid using the same variable name for a different purpose, such as storing a list of particular locations to execute at, or such as storing the results of calculating the taylor series at particular locations.

Torsten am 27 Sep. 2018

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n is undefined.
You use i as a loop variable in both nested loops.
Walter's remark.

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Walter Roberson am 22 Sep. 2018

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As I already explained to you, because you have

y = [ 3/2, x^2 + y(x)^2, 2*x + 2*y(x)*diff(y(x), x), 2*diff(y(x), x)^2 + 2*y(x)*diff(y(x), x, x) + 2]

then the y on the left side refers to the same thing as the y on the right side, and so y(x) on the right side signifies array indexing. Your y vector is 5 elements long, so the only valid values of x for this would be 1, 2, 3, 4, or 5. Each y(x) would resolve to a numeric scalar value, and diff() of a numeric scalar value is empty. Any operation involving an empty array returns an empty array, so all of the entries except the first two are going to disappear, leaving you only [3/2, x^2 + y(x)^2] to work with for preliminary consistency.

Now, with that subset, can x = 1 be made self-consistent? That would require that y(1) be 3/2, which seems plausible. With the subset, can x = 2 be made self-consistent? That would require that y(2) = x^2 + y(x)^2 = 2^2 + y(2)^2 . Rewriting as z = 4 + z^2 we can see that has only complex roots 1/2-1i*sqrt(15)*(1/2), 1/2+1i*sqrt(15)*(1/2) . Is that acceptable, to force y(2) to be complex valued?