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Consider the code below (MatLab):

w = 0 : 0.0001 : 9.4978;
a = [1    11    46    95   109    74    24];
b = [-1 3 4 3 1];
mu = 1;
a0 = a(7) ;a1 = a(6) ;a2 = a(5); a3 = a(4) ; a4 = a(3) ; a5 = a(2); a6 = a(1);
b0 = b(5);b1 = b(4);b2 = b(3) ; b3 = b(2); b4 = b(1) ;
De = -a6*w.^6 + a4*w.^4 - a2*w.^2 + a0;
Do = a5*w.^4 - a3*w.^2 + a1;
Ne = b4*w.^4 - b2*w.^2 + b0;
No = -b3*w.^2 + b1;
T = 0.01;
e = real((1i*w).^mu);
f = imag((1i*w).^mu);
A = Ne.*cos(T*w) + w.*No.*sin(T*w);  
B = e.*(Ne.*cos(T*w) + w.*No.*sin(T*w)) - f.*(w.*No.*cos(T*w) - Ne.*sin(T*w));
C = w.*No.*cos(T*w) - Ne.*sin(T*w);
D = e.*(w.*No.*cos(T*w) - Ne.*sin(T*w)) + f.*(Ne.*cos(T*w) + w.*No.*sin(T*w));
Kp = (-De.*D + w.*Do.*B)./(f.*(Ne.^2 + w.^2.*No.^2));
Kd = (-w.*Do.*A + De.*C)./(f.*(Ne.^2 + w.^2.*No.^2));
figure
plot(Kp,Kd)
line([-24 -24],[-2.24 9.813])

By running code we have this figure: enter image description here

I want to draw tangent lines on specified part of curve ( red part, w belongs to [0.6342,0.9985] ) : enter image description here

after doing that, my aim is to find maximum area of inward-pointing half plane defined by this line and curve between all possible areas which produced by tangent line(like this): enter image description here

another example with another tangent line at another point is:

enter image description here

and we can conclude first area is bigger than the second one. This approach should do for all points in red part.

How can I do it by MatLab?

I hope my question is clear. Any idea would be appreciated.

share|improve this question
4  
What have you had in mind to solve this? Is this really a programming issue? –  Eitan T Sep 16 '13 at 8:53
2  
This is a little ambiguous: "want to draw tangent lines on specified part of curve". You mean you want to draw a tangent at a specific point, or a bunch or tangents at a bunch of points in that stretch? Plus as EitanT points out, this is first a geometry problem. Once you solve that you can think about the programming. You may also want to consider using image processing tools to performing the task, if this is a graphical exercise. –  Try Hard Sep 16 '13 at 9:10
    
@EitanT I don't sure how to do it. That is why I posted this. –  Zakhar Sep 16 '13 at 11:39
    
@Zia But how is this really related to MALTAB? It's a theoretical problem. Once you figure out an approach to solving it, you can give it a go in MATLAB. –  Eitan T Sep 16 '13 at 11:47
1  
@TryHard I mean I want to draw "n tangent line at n distinct (but Consecutive) point"(n point belong to red part of curve). After searching among n area produced by n tangent line, determine maximum area and tangent line related to maximum area. (tangents at a bunch of points in red part). But I can't understand why you note this is a geometrical problem? What is your suggestion to using image processing tools? –  Zakhar Sep 16 '13 at 11:53

1 Answer 1

up vote 3 down vote accepted

This should work somehow.

% remove NaNs
Kd(1)=[];
Kp(1)=[];
%%

%exclude non relavant part of original curve
x=Kp;
y=Kd;
exc = 40000;
x(exc:1:end)=[];
y(exc:1:end)=[];

mask = find(x < -9 & x > -19);
xs = x(mask);
ys = y(mask);

L = length(xs)
%%
% determine area of original shape
A_total = polyarea(Kd,Kp);

% pre-allocation    
slope=zeros(L,1)';
inter = slope;
A_part = slope;

for ii = 1:1:L;
    % determine slope for every point
    xslope = xs(ii);
    idx_a = find(xs<xslope,1,'last');
    idx_b = find(xs>xslope,1,'first');
    xa = xs(idx_a);
    xb = xs(idx_b);
    slope(ii) = (ys(idx_b) - ys(idx_a))/(xb - xa);

    % determine slope between current point and any other one
    slopeX = (ys(ii)-y)./(xs(ii)-x);
    % determine intersection points of tangent with rest of curve
    [~,intersection] = min(abs((slopeX)-slope(ii)));
    % index of intersection
    inter(ii)=intersection;
end

% modify curve to get polygon
x_start = x(1);
x_end = x_start;
y_start = y(1);


%finally calculate all single area values A(ii)
for ii = 1:1:L;
    i_inter = inter(ii);
    y_end = y(i_inter) - (x(i_inter)- x_end)*slope(ii);
    x(i_inter+1) = x_end;
    y(i_inter+1) = y_end;
    A_part(ii) = A_total - polyarea( x(1:1:i_inter+1) ,y(1:1:i_inter+1) );
end

When you plot now A_part over x you get:

enter image description here

as a proof here all tangents: enter image description here

share|improve this answer
    
Thanks. It's seems reasonable. But I should check this much. Thanks again. –  Zakhar Sep 16 '13 at 17:16
    
@Zia hopefully last correction... don't worry I really like this question. –  thewaywewalk Sep 16 '13 at 18:01
1  
It's a nice numerical approach but the last part (determination of the area to exclude) doesn't appear to be quite right. Try for instance overlaying plot(x(1:1:i_inter+1) ,y(1:1:i_inter+1),'r:') onto the original curve... –  Try Hard Sep 16 '13 at 19:46
    
@TryHard you're right, I had another look at it. In the second plot you can see all tangents, now it seems right. (really!) :) –  thewaywewalk Sep 16 '13 at 21:46
    
@thewaywewalk looks much better! :) –  Try Hard Sep 16 '13 at 21:58

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