Solve equation for one unknown with one known parameter
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clear all
clc
a=0.5
x=linspace(-2*a,2*a,100)
eqn=@(x,y,a)(1/2*a^2)*[x^2./(2-(1-(x./(2*a))^2-(y./(2*a))^2)+sqrt((1-(x./(2*a))^2-(y./(2*a))^2)+(y./a)^2))-y^2./((1-(x./(2*a))^2-(y./(2*a))^2)+sqrt((1-(x./(2*a))^2-(y./(2*a))^2)+(y./a)^2))]-1==0;
solve(eqn,y)
Answer is
Unrecognized function or variable 'y'.
Error in naca (line 6)
solve(eqn,y)
how can I solve y for x matrix value
2 Comments
onur karakurt
on 18 May 2021
The actual equations are:
I = imread('https://www.mathworks.com/matlabcentral/answers/uploaded_files/621828/image.png');
figure
imshow(I)
.
Accepted Answer
Try something like this —
a=0.5;
% x=linspace(-2*a,2*a,100)
x=linspace(-2*a,2*a,20);
eqn=@(x,y,a)(1/2*a^2)*[x^2./(2-(1-(x./(2*a))^2-(y./(2*a))^2)+sqrt((1-(x./(2*a))^2-(y./(2*a))^2)+(y./a)^2))-y^2./((1-(x./(2*a))^2-(y./(2*a))^2)+sqrt((1-(x./(2*a))^2-(y./(2*a))^2)+(y./a)^2))]-1;
for k = 1:numel(x)
yv(k,:) = fsolve(@(y)eqn(x(k),y,a), 10);
end
Results = table(x', yv)
It might be necessary to use the uniquetol function to eliminate duplicate (or near-duplicate) values of ‘yv’ and thier associated ‘x’ values.
.
9 Comments
onur karakurt
on 18 May 2021
onur karakurt
on 18 May 2021
Star Strider
on 18 May 2021
I’m lost.
What variables are known, what variables are to be solved for?
The fsolve fucntion can solve systems such as these, however more needs to be known about them.
onur karakurt
on 18 May 2021
x and a are known, y unknown.
Now ı trying to find the roots of y because it is nonlinear function.
when I fits x and a to any constant to find equation answers against the y values from 0 to 1 with 100 pieces. I saw infinite roots of y, I guess. But it must be any solution for this.
clear all
clc
a=0.5;
x=0.5;
y=linspace(0,1,100);
for i=1:size(y)
y=y(i,:);
z=(1e15)*((x./(2*a*cos(asin(sqrt(((1-(x./(2*a)).^2-(y./(2*a)).^2)+sqrt((1-(x./(2*a)).^2-(y./(2*a)).^2).^2+(y./a).^2))./2))))).^2-(y./(2*a*sin(asin(sqrt(((1-(x./(2*a)).^2-(y./(2*a)).^2)+sqrt((1-(x./(2*a)).^2-(y./(2*a)).^2).^2+(y./a).^2))./2))))).^2-1);
end
plot(y,z)
onur karakurt
on 18 May 2021
Finding all the roots is going to be a challenge.
First, using fsolve (I also experimented with fzero) is not very revealing —
zfcn = @(x,y,a) (1e15)*((x./(2*a*cos(asin(sqrt(((1-(x./(2*a)).^2-(y./(2*a)).^2)+sqrt((1-(x./(2*a)).^2-(y./(2*a)).^2).^2+(y./a).^2))./2))))).^2-(y./(2*a*sin(asin(sqrt(((1-(x./(2*a)).^2-(y./(2*a)).^2)+sqrt((1-(x./(2*a)).^2-(y./(2*a)).^2).^2+(y./a).^2))./2))))).^2-1);
a=0.5;
x=linspace(-2*a,2*a,100);
S = zeros(numel(x),3);
for k = 1:numel(x)
[y,fv] = fsolve(@(y)zfcn(x(k),y,a), x(k));
S(k,:) = [x(k), y, fv];
end
Out = array2table(S,'VariableNames',{'x','y','FunctionValue'})
Second, a relatively easy way to determine the roots is to plot them using the contour function, drawing contours at the roots of ‘z’ —
y = linspace(-2*pi, 2*pi);
[Xm,Ym] = ndgrid(x,y);
Zm = zfcn(Xm,Ym,a);
figure
[M,h] = contour(Xm,Ym,Zm, [0 0]); % Draw Contours Only At z=0
grid
title('Contour Map of (x,y) Coordinates Where z=0')
xlabel('x')
ylabel('y')
% axis('equal')
Choose whatever limits you want for ‘y’. Here, I chose the interval 
.
. So there are myriad symmetrical roots —
format shortE
M
format short
See the documentation for contour and specifically for M to understand how to retrieve the values that contour creates.
This is the only way I can think of to solve this.
.
onur karakurt
on 19 May 2021
onur karakurt
on 19 May 2021
Star Strider
on 19 May 2021
As always, my pleasure!
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