How to find the coordinates of the point of intersection of a line and a curve?

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Neha Sinha
Neha Sinha am 5 Mär. 2019
Kommentiert: Star Strider am 5 Mär. 2019
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How to find the coordinates of the indicated point?

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Star Strider
Star Strider am 5 Mär. 2019
Add these lines to the end of the previous code (How to draw a tangent using a point and an angle?):
x2_near_origin_idx = find(x2 <= origin(1), 1, 'last');
B2 = [x2(x2_near_origin_idx) 1; x2(x2_near_origin_idx+1) 1] \ [y2(x2_near_origin_idx); y2(x2_near_origin_idx+1)]; % Equation Of Data Near ‘tangline’
Btl = [tangline(1,1) 1; tangline(1,2) 1] \ [tangline(2,1); tangline(2,2)]; % Equation Of ‘tangline’
xint = -(B2(2) - Btl(2)) / (B2(1) - Btl(1));
yint = [xint 1] * B2;
plot(xint, yint, '+r')
so the entire code is now:
filename1 = 'finalocc.xlsx';
filename2 = 'Nzpftest.xlsx';
values1 = xlsread(filename2,'Sheet1','A1:B7');
x1 = values1(:,1);
y1 = values1(:,2);
plot(y1,x1)
hold on
values2 = xlsread(filename1,'Sheet1','A2:B14');
x2 = values2(:,1);
y2 = values2(:,2);
plot(x2,y2, '.-')
dist= 0.32;
xx=interp1(y2,x2,50)
m=(50-0)/(xx-0);
deg= atand(m)
plot([1.68,2],[240.177,240.177])
% hold on
ad = 89.8412;
origin = [1.68;240.177];
lineLen = 20;
tangline = [0 cosd(ad);0 sind(ad)];
tangline = bsxfun(@plus, lineLen*[0 cosd(ad);0 sind(ad)], origin);
plot(tangline(1,:), tangline(2,:))
x2_near_origin_idx = find(x2 <= origin(1), 1, 'last');
B2 = [x2(x2_near_origin_idx) 1; x2(x2_near_origin_idx+1) 1] \ [y2(x2_near_origin_idx); y2(x2_near_origin_idx+1)]; % Equation Of Data Near ‘tangline’
Btl = [tangline(1,1) 1; tangline(1,2) 1] \ [tangline(2,1); tangline(2,2)]; % Equation Of ‘tangline’
xint = -(B2(2) - Btl(2)) / (B2(1) - Btl(1));
yint = [xint 1] * B2;
plot(xint, yint, '+r')
hold off
The point of intersection will be plotted as a red ‘+’ at (xint,yint).
  2 Kommentare
Neha Sinha
Neha Sinha am 5 Mär. 2019
Thank you so much :) .
x2_near_origin_idx = find(x2 <= origin(1), 1, 'last');
B2 = [x2(x2_near_origin_idx) 1; x2(x2_near_origin_idx+1) 1] \ [y2(x2_near_origin_idx); y2(x2_near_origin_idx+1)]; % Equation Of Data Near ‘tangline’
xint = -(B2(2) - Btl(2)) / (B2(1) - Btl(1));
yint = [xint 1] * B2;
Can you please explain this part?
Star Strider
Star Strider am 5 Mär. 2019
As always, my pleasure!
Sure.
The code needs to find the values of ‘x2’ that include ‘origin’, and the ‘x2_near_origin_idx’ calculation detects the 'last' index of ‘x2’ that is less than or equal to ‘origin(1)’. Here, that and the next largest index include the parts of (x2,y2) that include the limits of ‘tangline’. The code uses those coordinates to calculate linear parameter estimates of both lines in that region, calculating them as ‘B2’ for the data and ‘Btl’ for ‘tangline’. It then calculates ‘xint’ using simple algebra, and ‘yint’ using ‘xint’ and the parameters for one of the linear models. (Either one would work and produce the same value for ‘yint’. I chose ‘B2’ arbitrarily.)
This is fortunately a relatively straightforward problem. The code would be much more complicated if the beginning and end limits of ‘tangline’ crossed more than one segment of the data. That would likely involve generating estimates of both the data and ‘tangline’ with much higher resolution (using linspace and interp1) and initially subtracting them to find the approximate region of intersection. Then, a version of the same code here would calculate the intersection with greater precision.

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darova
darova am 5 Mär. 2019
x = linspace(0,2.7*pi,2);
y = 0.1*(x)+0.4;
x0 = linspace(2.7*pi, 4*pi,5);
x = [x x0];
y = [y sin(x0)+2.5];
x_ = linspace(0.5, 4*pi-0.5, 100);
y_ = sin(x_+pi)+1.3;
plot(x,y,x_,y_);
hold on
for i = 1:length(x)-1
a = (y(i+1)-y(i)) / (x(i+1) - x(i));
b = y(i) - a*x(i);
for j = 1:length(x_)-1
a_ = (y_(j+1)-y_(j)) / (x_(j+1) - x_(j));
b_= y_(j) - a_*x_(j);
X = (b-b_)/(a_-a);
if( X > x(i) && X < x(i+1) &&...
X > x_(j) && X < x_(j+1))
plot(X,a*X+b,'or')
end
end
end

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