Image:Parabolic trajectory.svg

From Wikipedia, the free encyclopedia

Parabolic_trajectory.svg (SVG file, nominally 641 × 265 pixels, file size: 8 KB)

Wikimedia Commons logo This is a file from the Wikimedia Commons. The description on its description page there is shown below.
Commons is a freely licensed media file repository. You can help.
Description

Illustration of a parabolic trajectory.
Source

self-made with MATLAB. Tweaked in Inkscape.
Date

05:58, 20 December 2007 (UTC)
Author

Oleg Alexandrov
Permission
(Reusing this image)

See below


Public domain I, the copyright holder of this work, hereby release it into the public domain. This applies worldwide.

In case this is not legally possible:
I grant anyone the right to use this work for any purpose, without any conditions, unless such conditions are required by law.

Afrikaans | Alemannisch | Aragonés | العربية | Asturianu | Български | Català | Česky | Cymraeg | Dansk | Deutsch | Eʋegbe | Ελληνικά | English | Español | Esperanto | Euskara | Estremeñu | فارسی | Français | Galego | 한국어 | हिन्दी | Hrvatski | Ido | Bahasa Indonesia | Íslenska | Italiano | עברית | Kurdî / كوردی | Latina | Lietuvių | Latviešu | Magyar | Македонски | Bahasa Melayu | Nederlands | ‪Norsk (bokmål)‬ | ‪Norsk (nynorsk)‬ | 日本語 | Polski | Português | Ripoarisch | Română | Русский | Shqip | Slovenčina | Slovenščina | Српски / Srpski | Svenska | ไทย | Tagalog | Türkçe | Українська | Tiếng Việt | Walon | ‪中文(简体)‬ | ‪中文(繁體)‬ | zh-yue-hant | +/-

[edit] Source code (MATLAB)

% illustration of a parabolic trajectory
 
function main()
 
   L=0.8;
   s=0.1;
   q=-0.4;
   N=100;
 
   arrow_size = 0.1;
   sharpness = 20;
   arrow_type = 1; 
   arrlen = 0.3; % arrow length
   tiny = 0.01;
   ball_radius = 0.05;
 
   X=linspace(-L, L, N);
   Y =L^2 - X.^2;
   Xl = linspace(-L-s, L+s, N);
 
 
% KSmrq's colors
   red    = [0.867 0.06 0.14];
   blue   = [0, 129, 205]/256;
   green  = [0, 200,  70]/256;
   yellow = [254, 194,   0]/256;
   white = 0.99*[1, 1, 1];
   black = [0, 0, 0];
   gray = 0.5*white;
   lw = 2.3;
 
 
   figure(1); clf; hold on; axis equal; axis off;
   plot(X, Y, 'linewidth', lw, 'linestyle', '--', 'color', blue);
   arrow([q-tiny, L^2-q^2], [q+arrlen-tiny, L^2-q^2-2*q*arrlen], lw, arrow_size, sharpness, arrow_type, red);
   ball(q, L^2 - q^2, ball_radius, gray)
   plot(Xl, 0*Xl, 'linewidth', 2*lw, 'color', black);
 
 
  %saveas(gcf, 'Parabolic_trajectory.eps', 'psc2')
  plot2svg('Parabolic_trajectory.svg');
 
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', [0, 0, 0]);
 
function arrow(start, stop, thickness, arrow_size, sharpness, arrow_type, color)
 
% Function arguments:
% start, stop:  start and end coordinates of arrow, vectors of size 2
% thickness:    thickness of arrow stick
% arrow_size:   the size of the two sides of the angle in this picture ->
% sharpness:    angle between the arrow stick and arrow side, in degrees
% arrow_type:   1 for filled arrow, otherwise the arrow will be just two segments
% color:        arrow color, a vector of length three with values in [0, 1]
 
% convert to complex numbers
   i=sqrt(-1);
   start=start(1)+i*start(2); stop=stop(1)+i*stop(2);
   rotate_angle=exp(i*pi*sharpness/180);
 
% points making up the arrow tip (besides the "stop" point)
   point1 = stop - (arrow_size*rotate_angle)*(stop-start)/abs(stop-start);
   point2 = stop - (arrow_size/rotate_angle)*(stop-start)/abs(stop-start);
 
   if arrow_type==1 % filled arrow
 
      % plot the stick, but not till the end, looks bad
      t=0.5*arrow_size*cos(pi*sharpness/180)/abs(stop-start); stop1=t*start+(1-t)*stop;
      plot(real([start, stop1]), imag([start, stop1]), 'LineWidth', thickness, 'Color', color);
 
      % fill the arrow
      H=fill(real([stop, point1, point2]), imag([stop, point1, point2]), color);
      set(H, 'EdgeColor', 'none')
 
   else % two-segment arrow
      plot(real([start, stop]), imag([start, stop]),   'LineWidth', thickness, 'Color', color); 
      plot(real([stop, point1]), imag([stop, point1]), 'LineWidth', thickness, 'Color', color);
      plot(real([stop, point2]), imag([stop, point2]), 'LineWidth', thickness, 'Color', color);
   end

File history

Click on a date/time to view the file as it appeared at that time.

Date/TimeDimensionsUserComment
current05:58, 20 December 2007641×265 (8 KB)Oleg Alexandrov ({{Information |Description=Illustration of a parabolic trajectory. |Source=self-made with MATLAB |Date=~~~~~ |Author= Oleg Alexandrov |Permission=See below |other_versions= }} {{PD-self}} ==Source code (MATLAB)== )
The following pages on the English Wikipedia link to this file (pages on other projects are not listed):