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Summary

Description
English: Argument principle. The simple contour C (black), the zeros of f (blue) and the poles of f (red). Here we have
Source Own work
Author
Public domain This work has been released into the public domain by its author, Oleg Alexandrov. This applies worldwide.

In some countries this may not be legally possible; if so:
Oleg Alexandrov grants anyone the right to use this work for any purpose, without any conditions, unless such conditions are required by law.

Other versions



The original description page was here. All following user names refer to en.wikipedia.

Made by myself with Matlab

Public domain This work has been released into the public domain by its author, Oleg Alexandrov. This applies worldwide.

In some countries this may not be legally possible; if so:
Oleg Alexandrov grants anyone the right to use this work for any purpose, without any conditions, unless such conditions are required by law.

Source code (MATLAB)

Source code. The function arrow() used here is written and copyrighted by somebody else. I don't know the terms. Everything else is written by me, which I put in the public domain.

function main() % draw a closed spline curve with some points inside 

   curve_linewidth=1.8;  arrowsize=8; arrow_type=2; % make filled trig arrow
   ball_radius=0.015; % how big to make the points representing the zeros

   x=[0 1 1.2 0 0]; y=[0 0.1 1 1 0.5];  % points the spline will go thru

   n=length(x); 
   P=5; Q=n+2*P+1; % P will denote the amount of overlap of the path with itself
   
% Make the 'periodic' sequence xp=[x(1) x(2) x(3) ... x(n) x(1) x(2) x(3) ... ]
% of length Q. Same for yp.
   for i=1:Q
      j=rem(i, n)+1; % rem() is the remainder of division of i by n
      xp(i)=x(j);
      yp(i)=y(j);
   end

% do the spline interpolation
   t=1:length(xp);
   N=100; % how fine to make the interpolation
   tt=1:(1/N):length(xp);
   xx=spline(t, xp, tt);
   yy=spline(t, yp, tt);

% discard the redundant overlap pieces
   start=N*(P-1)+1;
   stop=N*(n+P-1)+1;
   xx=xx(start:stop); 
   yy=yy(start:stop);

   figure(1); clf; hold on; axis equal; axis off; % prepare the screen
   plot(xx, yy, 'k', 'LineWidth', curve_linewidth)% plot the path

% plot the residues and the poles -- see the ball() function below
   ball(0.5,       0.7,    ball_radius, [1, 0, 0]); % red
   ball(0.3187,    0.3024, ball_radius, [0, 0, 1]); % blue
   ball(0.7231,    0.4441, ball_radius, [0, 0, 1]);
   ball(0.7981,    0.7776, ball_radius, [0, 0, 1]);
   ball(0.2854,    0.8026, ball_radius, [1, 0, 0]);
   ball(0.6397,    0.1773, ball_radius, [1, 0, 0]);
   ball(0.2896,    0.5525, ball_radius, [0, 0, 1]);
   ball(0.9774,    0.5817, ball_radius, [1, 0, 0]);
   ball(0.6189,    1.0068, ball_radius, [1, 0, 0]);

   % place the two arrows showing the orientation of the contour
   shift=80; arrow([xx(shift) yy(shift)], [xx(shift+10) yy(shift+10)], ...
		   curve_linewidth, arrowsize, pi/8,arrow_type, [0, 0, 0])
   shift=270; arrow([xx(shift) yy(shift)], [xx(shift+10) yy(shift+10)], ...
		    curve_linewidth, arrowsize, pi/8,arrow_type, [0, 0, 0])

   axis([min(xx)-1, max(xx)+1, min(yy)-1, max(yy)+1]); % image frame

   saveas(gcf, 'argument_principle.eps', 'psc2')% save to file
   disp('Saved to argument_principle.eps. Get antialiased .png in an editor.')

   %%%%%%%%%%%%%%%%%%%%% auxiliary functions ball() and arrow() %%%%%%%%%%%%%%%%%%

function ball(x, y, radius, color) % draw a ball of given uniform color 
   Theta=0:0.1:2*pi;
   X=radius*cos(Theta)+x;
   Y=radius*sin(Theta)+y;
   H=fill(X, Y, color);
   set(H, 'EdgeColor', color);

function arrow(start, stop, thickness, arrowsize, sharpness, arrow_type, color)
   
%  draw a line with an arrow at the end
%  start is the x,y point where the line starts
%  stop is the x,y point where the line stops
%  thickness is an optional parameter giving the thickness of the lines   
%  arrowsize is an optional argument that will give the size of the arrow 
%  It is assumed that the axis limits are already set
%  0 < sharpness < pi/4 determines how sharp to make the arrow
%  arrow_type draws the arrow in different styles. Values are 0, 1, 2, 3.
   
%       8/4/93    Jeffery Faneuff
%       Copyright (c) 1988-93 by the MathWorks, Inc.
%       Modified by Oleg Alexandrov 2/16/03

   
   if nargin <=6
      color=[0, 0, 0]; % default color
   end
   
   if (nargin <=5)
      arrow_type=0;   % the default arrow, it looks like this: ->
   end
   
   if (nargin <=4)
      sharpness=pi/4; % the arrow sharpness - default = pi/4
   end

   if nargin<=3
      xl = get(gca,'xlim');
      yl = get(gca,'ylim');
      xd = xl(2)-xl(1);            
      yd = yl(2)-yl(1);            
      arrowsize = (xd + yd) / 2;   % this sets the default arrow size
   end

   if (nargin<=2)
      thickness=0.5; % default thickness
   end
   
   
   xdif = stop(1) - start(1); 
   ydif = stop(2) - start(2);

   if (xdif == 0)
      if (ydif >0) 
	 theta=pi/2;
      else
	 theta=-pi/2;
      end
   else
      theta = atan(ydif/xdif);  % the angle has to point according to the slope
   end

   if(xdif>=0)
      arrowsize = -arrowsize;
   end

   if (arrow_type == 0) % draw the arrow like two sticks originating from its vertex
      xx = [start(1), stop(1),(stop(1)+0.02*arrowsize*cos(theta+sharpness)),...
	    NaN,stop(1), (stop(1)+0.02*arrowsize*cos(theta-sharpness))];
      yy = [start(2), stop(2), (stop(2)+0.02*arrowsize*sin(theta+sharpness)),...
	    NaN,stop(2), (stop(2)+0.02*arrowsize*sin(theta-sharpness))];
      plot(xx,yy, 'LineWidth', thickness, 'color', color)
   end

   if (arrow_type == 1)  % draw the arrow like an empty triangle
      xx = [stop(1),(stop(1)+0.02*arrowsize*cos(theta+sharpness)), ...
	    stop(1)+0.02*arrowsize*cos(theta-sharpness)];
      xx=[xx xx(1) xx(2)];
      
      yy = [stop(2),(stop(2)+0.02*arrowsize*sin(theta+sharpness)), ...
	    stop(2)+0.02*arrowsize*sin(theta-sharpness)];
      yy=[yy yy(1) yy(2)];

      plot(xx,yy, 'LineWidth', thickness, 'color', color)
      
%     plot the arrow stick
      plot([start(1), stop(1)+0.02*arrowsize*cos(theta)*cos(sharpness)],  ...
	   [start(2), stop(2)+0.02*arrowsize*sin(theta)*cos(sharpness)], ...
	   'LineWidth', thickness, 'color', color)
      
   end
   
   if (arrow_type==2) % draw the arrow like a full triangle
      xx = [stop(1),(stop(1)+0.02*arrowsize*cos(theta+sharpness)), ...
	    stop(1)+0.02*arrowsize*cos(theta-sharpness),stop(1)];
      
      yy = [stop(2),(stop(2)+0.02*arrowsize*sin(theta+sharpness)), ...
	    stop(2)+0.02*arrowsize*sin(theta-sharpness),stop(2)];
      H=fill(xx, yy, color);% fill with black
      set(H, 'EdgeColor', 'none')
      
%     plot the arrow stick
      plot([start(1) stop(1)+0.01*arrowsize*cos(theta)], ...
           [start(2),     stop(2)+0.01*arrowsize*sin(theta)], ...
	 'LineWidth', thickness, 'color', color)
   end

   if (arrow_type==3) % draw the arrow like a filled 'curvilinear' triangle
      curvature=0.5; % change here to make the curved part more (or less) curved
      radius=0.02*arrowsize*max(curvature, tan(sharpness));
      x1=stop(1)+0.02*arrowsize*cos(theta+sharpness);
      y1=stop(2)+0.02*arrowsize*sin(theta+sharpness);
      x2=stop(1)+0.02*arrowsize*cos(theta)*cos(sharpness);
      y2=stop(2)+0.02*arrowsize*sin(theta)*cos(sharpness);
      d1=sqrt((x1-x2)^2+(y1-y2)^2);
      d2=sqrt(radius^2-d1^2);
      d3=sqrt((stop(1)-x2)^2+(stop(2)-y2)^2);
      center(1)=stop(1)+(d2+d3)*cos(theta);
      center(2)=stop(2)+(d2+d3)*sin(theta);

      alpha=atan(d1/d2);
      Alpha=-alpha:0.05:alpha;
      xx=center(1)-radius*cos(Alpha+theta);
      yy=center(2)-radius*sin(Alpha+theta);
      xx=[xx stop(1) xx(1)];
      yy=[yy stop(2) yy(1)];

      H=fill(xx, yy, color);% fill with black
      set(H, 'EdgeColor', 'none')

%     plot the arrow stick
      plot([start(1) center(1)-radius*cos(theta)], [start(2), center(2)- ...
		    radius*sin(theta)], 'LineWidth', thickness, 'color', color);
   end
date/time username edit summary
19:16, 7 March 2006 en:User:141.140.104.11 (fix deprecated cp tag)
01:01, 13 June 2005 en:User:Oleg Alexandrov (replacing "thru" with "through" in comments of computer code is a bit excessive.)
22:09, 12 June 2005 en:User:Bratsche ('thru' -> 'through'; -- <a href="/wiki/User:Humanbot" title="User:Humanbot">Join and fix more!</a>)
23:19, 15 January 2005 en:User:Oleg Alexandrov (added source code.)
18:04, 15 January 2005 en:User:Oleg Alexandrov (Made by myself with Matlab {{PD}})

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Argument principle

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Date/TimeThumbnailDimensionsUserComment
current15:25, 5 June 2007Thumbnail for version as of 15:25, 5 June 2007200 × 168 (7 KB)Oleg Alexandrov{{Information |Description=Made by myself with Matlab |Source=Originally from [http://en.wikipedia.org en.wikipedia]; description page is/was [http://en.wikipedia.org/w/index.php?title=Image%3AArgument_principle1.png here]. |Date=2005-01-15 (original upl
17:12, 18 March 2006Thumbnail for version as of 17:12, 18 March 2006200 × 168 (7 KB)MaksimLa bildo estas kopiita de wikipedia:en. La originala priskribo estas: Made by myself with Matlab {{PD-user|Oleg Alexandrov}} Source code. The function arrow() used here is written and copyrighted by somebody else. I don't know the terms. Everything else

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