Archivo:Sphere wireframe.svg
Tamaño de esta previsualización PNG del archivo SVG: 400 × 400 píxeles. Otras resoluciones: 240 × 240 píxeles · 480 × 480 píxeles · 768 × 768 píxeles · 1024 × 1024 píxeles · 2048 × 2048 píxeles.
Ver la imagen en su resolución original ((Imagen SVG, nominalmente 400 × 400 pixels, tamaño de archivo: 8 kB))
Resumen
| Descripción |
English: Sphere wireframe - orthogonal projection of a sphere. The image shows lines, which are drawn as they were painted onto the surface of a sphere. The angular distance between two lines is 10°. The SVG file is created by the below C++-program, which calculates each edge of a line as an ellipse-bow. The backside of the sphere has an opacity of 0.25. The axis tilt is 52.5°. |
| Fecha | |
| Fuente | Trabajo propio |
| Autor | Geek3 |
| Otras versiones | Sphere wireframe 10deg 10r.svg |
W3C-validity not checked.
Source Code
This image can be completely generated by the following source code. If you have the gnu compiler collection installed, the programm can be compiled by the following commands:
g++ sphere_wireframe.cpp -o sphere_wireframe
and run :
./sphere_wireframe > Sphere_wireframe.svg
It creates file Sphere_wireframe.svg in working directory. This file can be viewed using rsvg-view program :
rsvg-view Sphere_wireframe.svg
Here is cpp code in file : sphere_wireframe.cpp
/* sphere - creates a svg vector-graphics file which depicts a wireframe sphere
*
* Copyright (C) 2008 Wikimedia foundation
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you can either send email to this
* program's author (see below) or write to:
* The Free Software Foundation, Inc.
* 51 Franklin Street, Fifth Floor
* Boston, MA 02110-1301 USA
*/
/* The expressions in this code are not proven to be correct.
* Hence this code probably contains lots of bugs. Be aware! */
#include <iostream>
#include <cmath>
#include <cstdlib>
#include <cstring>
using namespace std;
const double PI = 3.1415926535897932;
const double DEG = PI / 180.0;
/********************************* settings **********************************/
int n_lon = 18; // number of latitude fields (18 => 10° each)
int n_lat = 18; // half number of longitude fields (18 => 10° each)
double lon_offset = 2.5 * DEG; // offset of the meridians
double w = 52.5 * DEG; // axial tilt (0° => axis is perpendicular to image plane)
double stripe_grad = 0.5 * DEG; // width of each line
int image_size = 400; // width and height of the image in pixels
double back_opacity = 0.25; // opacity of the sphere's backside
char color[] = "#334070"; // color of lines
int istep = 2; // svg code indentation step
/*****************************************************************************/
double sqr(double x)
{
return(x * x);
}
// commands for svg-code:
void indent(int n, bool in_tag = false)
{
n *= istep;
if (in_tag) n += istep + 1;
for (int i = 0; i < n; i++) cout << " ";
}
void M()
{
cout << "M ";
}
void Z()
{
cout << "Z ";
}
void xy(double x, double y)
{
cout << x << ",";
cout << y << " ";
}
void arc(double a, double b, double x_axis_rot, bool large_arc, bool sweep)
{ // draws an elliptic arc
if (b < 0.5E-6)
{ // flat ellipses are not rendered properly => use line
cout << "L ";
}
else
{
cout << "A ";
cout << a << ","; // semi-major axis
cout << b << " "; // semi-minor axis
cout << x_axis_rot << " ";
cout << large_arc << " ";
cout << sweep << " ";
}
}
void circle(bool clockwise)
{
M();
xy(-1, 0);
arc(1, 1, 0, 0, !clockwise);
xy(1, 0);
arc(1, 1, 0, 0, !clockwise);
xy(-1, 0);
Z();
}
void start_svg_file()
{
cout << "<?xml version=\"1.0\" encoding=\"UTF-8\" standalone=\"no\"?>\n";
cout << "<svg id=\"Sphere_wireframe\"\n";
cout << " version=\"1.1\"\n";
cout << " baseProfile=\"full\"\n";
cout << " xmlns=\"http://www.w3.org/2000/svg\"\n";
cout << " xmlns:xlink=\"http://www.w3.org/1999/xlink\"\n";
cout << " width=\"" << image_size << "\"\n";
cout << " height=\"" << image_size << "\">\n\n";
cout << " <title>Sphere wireframe</title>\n\n";
cout << " <desc>\n";
cout << " about: http://commons.wikimedia.org/wiki/Image:Sphere_wireframe.svg\n";
cout << " rights: GNU Free Documentation license,\n";
cout << " Creative Commons Attribution ShareAlike license\n";
cout << " </desc>\n\n";
cout << " <g id=\"sphere\" transform=\"scale(" << 0.5 * image_size;
cout << ", " << -0.5 * image_size << ") translate(1, -1)\">\n";
}
void end_svg_file()
{
cout << " </g>\n</svg>\n";
}
int main (int argc, char *argv[])
{
// accept -lat and -lon as parameter
for (int i = 2; i < argc; i++)
{
if (isdigit(argv[i][0]) || (sizeof(argv[i]) > sizeof(char)
&& isdigit(argv[i][1])
&& (argv[i][0] == '.' || argv[i][0] == '-')))
{
if (strcmp(argv[i - 1], "-lon") == 0)
{
lon_offset = atof(argv[i]) * DEG;
}
if (strcmp(argv[i - 1], "-lat") == 0)
{
w = atof(argv[i]) * DEG;
}
}
}
double cosw = cos(w), sinw = sin(w);
double d = 0.5 * stripe_grad;
start_svg_file();
int ind = 2; // initial indentation level
indent(ind);
cout << "<g id=\"sphere_back\" transform=\"rotate(180)\" ";
cout << "opacity=\"" << back_opacity << "\">\n";
indent(++ind);
cout << "<g id=\"sphere_half\">\n";
// meridians
indent(++ind); cout << "<g id=\"meridians\"\n";
indent(ind++, true);
cout << "style=\"stroke:none; fill:" << color << "; fill_rule:evenodd\">\n";
double a = abs(cos(d));
for (int i_lon = 0; i_lon < n_lat; i_lon++)
{ // draw one meridian
double longitude = lon_offset + (i_lon * 180.0 / n_lat) * DEG;
double lon[2];
lon[0] = longitude + d;
lon[1] = longitude - d;
indent(ind);
cout << "<path id=\"meridian";
cout << i_lon << "\"\n";
indent(ind, true);
cout << "d=\"";
double axis_rot = atan2(-1.0 / tan(longitude), cosw);
if (sinw < 0)
axis_rot += PI;
double w2 = sin(longitude) * sinw;
double b = abs(w2 * cos(d));
double sinw1 = sin(d) / sqrt(1.0 - sqr(sin(longitude) * sinw));
if (abs(sinw1) >= 1.0)
{ // stripe covers edge of the circle
double w3 = sqrt(1.0 - sqr(w2)) * sin(d);
circle(false);
// ellipse
M();
xy(sin(axis_rot) * w3 - cos(axis_rot) * a,
-cos(axis_rot) * w3 - sin(axis_rot) * a);
arc(a, b, axis_rot / DEG, 0, 0);
xy(sin(axis_rot) * w3 + cos(axis_rot) * a,
-cos(axis_rot) * w3 + sin(axis_rot) * a);
arc(a, b, axis_rot / DEG, 0, 0);
xy(sin(axis_rot) * w3 - cos(axis_rot) * a,
-cos(axis_rot) * w3 - sin(axis_rot) * a);
Z();
}
else
{ // draw a disrupted ellipse bow
double w1 = asin(sinw1);
M();
xy(-cos(axis_rot + w1), -sin(axis_rot + w1));
arc(a, b, axis_rot / DEG, 1, 0);
xy(cos(axis_rot - w1), sin(axis_rot - w1));
arc(1, 1, 0, 0, 1);
xy(cos(axis_rot + w1), sin(axis_rot + w1));
arc(a, b, axis_rot / DEG, 0, 1);
xy(-cos(axis_rot - w1), -sin(axis_rot - w1));
arc(1, 1, 0, 0, 1);
xy(-cos(axis_rot + w1), -sin(axis_rot + w1));
}
Z();
cout << "\" />\n";
}
indent(--ind); cout << "</g>\n";
cout << endl;
// circles of latitude
indent(ind); cout << "<g id=\"circles_of_latitude\"\n";
indent(ind, true);
cout << "style=\"stroke:none; fill:" << color << "; fill_rule:evenodd\">\n";
ind++;
for (int i_lat = 1; i_lat < n_lon; i_lat++)
{ // draw one circle of latitude
double latitude = (i_lat * 180.0 / n_lon - 90.0) * DEG;
double lat[2];
lat[0] = latitude + d;
lat[1] = latitude - d;
double x[2], yd[2], ym[2];
for (int i = 0; i < 2; i++)
{
x[i] = abs(cos(lat[i]));
yd[i] = abs(cosw * cos(lat[i]));
ym[i] = sinw * sin(lat[i]);
}
double h[4]; // height of each point above image plane
h[0] = sin(lat[0] + w);
h[1] = sin(lat[0] - w);
h[2] = sin(lat[1] + w);
h[3] = sin(lat[1] - w);
if (h[0] > 0 || h[1] > 0 || h[2] > 0 || h[3] > 0)
{ // at least any part visible
indent(ind);
cout << "<path id=\"circle_of_latitude";
cout << i_lat << "\"\n";
indent(ind, true);
cout << "d=\"";
for (int i = 0; i < 2; i++)
{
if ((h[2*i] >= 0 && h[2*i+1] >= 0)
&& (h[2*i] > 0 || h[2*i+1] > 0))
{ // complete ellipse
M();
xy(-x[i], ym[i]); // startpoint
for (int z = 1; z > -2; z -= 2)
{
arc(x[i], yd[i], 0, 1, i);
xy(z * x[i], ym[i]);
}
Z();
if (h[2-2*i] * h[3-2*i] < 0)
{ // partly ellipse + partly circle
double yp = sin(lat[1-i]) / sinw;
double xp = sqrt(1.0 - sqr(yp));
if (sinw < 0)
{
xp = -xp;
}
M();
xy(-xp, yp);
arc(x[1-i], yd[1-i], 0,
sin(lat[1-i]) * cosw > 0, cosw >= 0);
xy(xp, yp);
arc(1, 1, 0, 0, cosw >= 0);
xy(-xp, yp);
Z();
}
else if (h[2-2*i] <= 0 && h[3-2*i] <= 0)
{ // stripe covers edge of the circle
circle(cosw < 0);
}
}
}
if ((h[0] * h[1] < 0 && h[2] <= 0 && h[3] <= 0)
|| (h[0] <= 0 && h[1] <= 0 && h[2] * h[3] < 0))
{
// one slice visible
int i = h[0] <= 0 && h[1] <= 0;
double yp = sin(lat[i]) / sinw;
double xp = sqrt(1.0 - yp * yp);
M();
xy(-xp, yp);
arc(x[i], yd[i], 0, sin(lat[i]) * cosw > 0, cosw * sinw >= 0);
xy(xp, yp);
arc(1, 1, 0, 0, cosw * sinw < 0);
xy(-xp, yp);
Z();
}
else if (h[0] * h[1] < 0 && h[2] * h[3] < 0)
{
// disrupted ellipse bow
double xp[2], yp[2];
for (int i = 0; i < 2; i++)
{
yp[i] = sin(lat[i]) / sinw;
xp[i] = sqrt(1.0 - sqr(yp[i]));
if (sinw < 0) xp[i] = -xp[i];
}
M();
xy(-xp[0], yp[0]);
arc(x[0], yd[0], 0, sin(lat[0]) * cosw > 0, cosw >= 0);
xy(xp[0], yp[0]);
arc(1, 1, 0, 0, 0);
xy(xp[1], yp[1]);
arc(x[1], yd[1], 0, sin(lat[1]) * cosw > 0, cosw < 0);
xy(-xp[1], yp[1]);
arc(1, 1, 0, 0, 0);
xy(-xp[0], yp[0]);
Z();
}
cout << "\" />\n";
}
}
for (int i = 0; i < 3; i++)
{
indent(--ind);
cout << "</g>\n";
}
indent(ind--);
cout << "<use id=\"sphere_front\" xlink:href=\"#sphere_half\" />\n";
end_svg_file();
}
Licencia
Yo, titular de los derechos de autor de esta obra, la publico en los términos de las siguientes licencias:
|
Se autoriza la copia, distribución y modificación de este documento bajo los términos de la licencia de documentación libre GNU, versión 1.2 o cualquier otra que posteriormente publique la Fundación para el Software Libre; sin secciones invariables, textos de portada, ni textos de contraportada. Se incluye una copia de la dicha licencia en la sección titulada Licencia de Documentación Libre GNU. |
Este archivo se encuentra bajo la licencia Creative Commons Attribution-Share Alike 3.0 Unported, 2.5 Generic, 2.0 Generic and 1.0 Generic
- Eres libre:
- de compartir – de copiar, distribuir y transmitir el trabajo
- de remezclar – de adaptar el trabajo
- Bajo las siguientes condiciones:
- atribución – Debes otorgar el crédito correspondiente, proporcionar un enlace a la licencia e indicar si realizaste algún cambio. Puedes hacerlo de cualquier manera razonable pero no de manera que sugiera que el licenciante te respalda a ti o al uso que hagas del trabajo.
- compartir igual – En caso de mezclar, transformar o modificar este trabajo, deberás distribuir el trabajo resultante bajo la misma licencia o una compatible como el original.
Puedes usar la licencia que prefieras.
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| Fecha y hora | Miniatura | Dimensiones | Usuario | Comentario | |
|---|---|---|---|---|---|
| actual | 16:10 23 nov 2008 | | 400 × 400 (8 kB) | Geek3 | {{Information |Description={{en|1=Sphere wireframe - the image shows lines, which are drawn as they were painted onto the surface of a sphere. The distance between two lines is 10°. The svg file is created by the below c++-program, which calculates each |
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- Mathematrix: Werkzeuge/ Abstellraum/ PSA/ Geometrie des Raums G2A
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