# Tag Info

76

One way you can do it is to start with a platonic solid with triangular sides - an octahedron, for example. Then, take each triangle and recursively break it up into smaller triangles, like so: Once you have a sufficient amount of points, you normalize their vectors so that they are all a constant distance from the center of the solid. This causes the ...

31

It is a little complicated, but you can draw all the objects by the following code: # -*- coding: utf-8 -*- from mpl_toolkits.mplot3d import Axes3D import matplotlib.pyplot as plt import numpy as np from itertools import product, combinations fig = plt.figure() ax = fig.gca(projection='3d') ax.set_aspect("equal") #draw cube r = [-1, 1] for s, e in ...

26

This is known as packing points on a sphere, and there is no (known) general, perfect solution. However, there are plenty of imperfect solutions. The three most popular seem to be: Create a simulation. Treat each point as an electron constrained to a sphere, then run a simulation for a certain number of steps. The electrons' repulsion will naturally ...

25

Since you've tagged this with OpenGL ES 2.0, let me suggest an alternative approach for creating smooth spheres, and that's to draw them as raytraced impostors. Rather than calculate the many vertices you'll need to replicate a smooth sphere, you can take advantage of the fact that a sphere looks pretty much the same from any angle. To do this, you employ a ...

24

The largest distance between any two points in a set S of points is called the diameter. Finding the diameter of a set of points is a well-known problem in computational geometry. In general, there are two steps here: Find the three-dimensional convex hull composed of the center of each sphere -- say, using the quickhull implementation in CGAL. Find the ...

14

I think that an easier algorithm is Pick a random point inside the [-1,1]x[-1,1]x[-1,1] cube If x*x + y*y + z*z > 1 repeat from 1 Normalize dividing x, y and z by Math.sqrt(x*x + y*y + z*z) in other words just pick a random point inside the sphere and project on the sphere. You can see this algorithm in action on this link. Note that if you use ...

14

I guess it should not be difficult to find the spherical polar coordinates from x,y,z (3d-coordinate system). sorry for i don't know latex. r is always constant if it's on surface. (90 - θ) your latitude (negative means it's on the bottom) as it's measured from top. φ is your longitude. (but not quite sure about longitude system) Also ...

14

This turned out to be a fun exercise; nice question! At first, you ask specifically for drawing such a sphere on a TImage, but that component is supposed to be used for showing graphics. Sure, it has a canvas on which can be drawn, but hereunder I use a TPaintBox which is the preferred component for own painting. Because, you will have to paint this ...

11

While I prefer the discarding method for spheres, for completeness I offer the exact solution. In spherical coordinates, taking advantage of the sampling rule: phi = random(0,2pi) costheta = random(-1,1) u = random(0,1) theta = arccos( costheta ) r = R * cuberoot( u ) now you have a (r, theta, phi) group which can be transformed to (x, y, z) in the ...

8

I believe this is the effect you are looking for: This is created using a radial gradient. The gradient starts with a radius of 0 and ends with a radius of the size of the circle. The center point of the start must be within the circle created by the end, or you will get a cone shape instead. Here is the code I used to make this image (a couple parts need ...

8

Before you start with anything in OpenGL ES, here is some advice: Avoid bloating CPU/GPU performance Removing intense cycles of calculations by rendering the shapes offline using another program will surely help. These programs will provide additional details about the shapes/meshes apart from exporting the resultant collection of points [x,y,z] ...

7

Copy and Pasting some code I originally wrote in How do i create a 3D Sphere in Opengl using Visual C++ class SolidSphere { protected std::vector<GLfloat> vertices; std::vector<GLfloat> normals; std::vector<GLfloat> texcoords; std::vector<GLushort> indices; public: void SolidSphere(float radius, unsigned int ...

7

I think this will do it. You should be able to reproduce this result by just copy-pasting the code below. You will need to have the latitude and longitude data in a file called longitude and latitude.txt. You can copy-paste the original sample data which is included below the code. If you have mplotlib it will additionally produce the plot below For ...

6

After some rearranging you can get the "nice" forms (1) 1/2 z^2 = (alpha) / ( y^2 - x^2) + 1 (2) 1/2 y^2 = (beta) / ( z^2 - x^2) + 1 (3) 1/2 x^2 = (gamma) / ( y^2 - z^2) + 1 where alpha = sx^2-sy^2 , beta = sx^2 - sz^2 and gamma = sz^2 - sy^2. Verify this yourself. Now I neither have the motivation nor the time but from this point on its pretty ...

6

in this example code node[k] is just the kth node. you are generating an array N points and node[k] is the kth (from 0 to N-1). if that is all that is confusing you, hopefully you can use that now. (in other words, k is an array of size N that is defined before the code fragment starts, and which contains a list of the points). alternatively, building on ...

6

If you actually read the helpfile for sphere before you used the example code, you'd read that sphere generates coordinates for a unit sphere. That is, the default sphere has radius 1. To change coordinates for a sphere of radius 1 to a sphere of radius r you just multiply them by r: [x,y,z] = sphere(); r = 5; surf( r*x, r*y, r*z ) % sphere with radius 5 ...

6

The cube algorithm will not give an even distribution over the sphere - in particular the areas near the projections of the corners will have the densest distribution of points and near the centers of the faces of the cubes will be the lowest. You can understand this intuitively since the volume of cube projected onto the underlying sphere is larger near ...

5

The answer is very simple you need to map your texture coordinates over the edge. The implementation depends on your data set but here is a stab at the problem. In computer graphics texture coordinates are stored on the faces and not on the vertices and your problem shows the reason. When you map a texture around a sphere, let us say in 10 steps you start ...

5

You cannot generate texture coordinates like that. The problem is that really quite simple. At 359 degrees, the S texture coordinate will be something like 0.95 or so. Close to 1.0, but not equal to 1.0. At 0 degrees, which physically is a position directly adjacent to the last position, the texture coordinate will be 0.0. So you will interpolate between ...

5

Here's a couple of suggestions: Create a vertex buffer object (VBO) containing the sphere and render this instead of using glutSolidSphere. Look into instancing, that is drawing many spheres with a single draw call. The following article does almost exactly what you want: http://sol.gfxile.net/instancing.html

5

I think you can use delaunay to create a triangulation and plot that using trimesh or trisurf. Both trimesh as trisurf accepts a fourth argument to specify the color of each vertex, add the option 'facecolor','interp' to interpolate the color of each face between vertices. edit: I experimented a bit further on it, and since it's a sphere, I think convhull ...

5

I have a function lying around here that is able to generate a triangulation of the sphere up to arbitrary precision. It's a function I've based on buildsphere by Giaccari Luigi, who sadly has disappeared off the internet completely (along with this function). So, I'll post it here, and on my File Exchange account. Once that gets approved, I'll replace this ...

5

If you are looking to create a glow-style effect, I have a written a number of examples at http://stemkoski.github.io/Three.js/ that may be helpful, including: http://stemkoski.github.io/Three.js/Selective-Glow.html with accompanying blog post http://stemkoski.blogspot.com/2013/03/using-shaders-and-selective-glow.html as well as the more ...

4

I want to give gmatt credit for this because he's done a lot of the work. The only difference in our answers is the equation for x. To do the inverse mapping from sphere to cube first determine the cube face the sphere point projects to. This step is simple - just find the component of the sphere vector with the greatest length like so: // map the given ...

4

The collision part is easy. Check if the distance between the spheres centers is less than the sum of their radius. As for the bounce, you need to swap the velocity amounts that contribute to the total velocity perpendicular to the collision of the spheres. (Assuming all your spheres have equal mass, it would be different for a combination of different ...

4

When I was doing openGL stuff, I quickly stuck to using just triangles. They are special in that a triangle is not ambiguous in any way. You example though, I would imagine this will work, though probably with artefacts. how you split a rectangle shouldn't matter, just as long as you pay attention to which way your triangles are wound, which way you ...

4

The easiest thing to do is to use the glu functions. I work mostly in C, but in Java it's probably something like: import net.java.games.jogl.GL; import net.java.games.jogl.GLU; import net.java.games.jogl.GLUquadric; ... GLUquadric quad = glu.gluNewQuadric(); glu.gluSphere(quad, 2, 10, 15); glu.gluDeleteQuadric(quad); This will create a sphere of ...

4

For the simplest projection (along the line connecting the point to the center of the sphere): Write the point in a coordinate system centered at the center of the sphere (x0,y0,z0): P = (x',y',z') = (x - x0, y - y0, z - z0) Compute the length of this vector: |P| = sqrt(x'*x' + y'*y' * z'*z') Scale the vector so that it has length equal to the radius of ...

4

glBufferData(GL_VERTEX_ARRAY,sphereSize, &ballVerts, GL_STATIC_DRAW); ballVerts is not an array. It is a std::vector. Taking the address of a std::vector doesn't get the address of the array contained within the vector. You need to use &ballVerts[0];

4

The issue is because you're wrapping texcoords around the sphere. If I take a horizontal slice of your globe and stretch it out flat, the x texcoords look something like this; 0.7 0.8 0.9 0 0.1 0.2 0.3 0.4 |------|------|------|------|------|------|------| ^^^^^^ |-wrapping around here The ...

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