Wikipedija

Slika:BMonSphere.jpg

BMonSphere.jpg(365 × 356 točk, velikost datoteke: 10 KB, MIME-vrsta: image/jpeg)

Logotip Zbirke
Logotip Zbirke
Datoteka je shranjena v Wikimedijini zbirki prostega slikovnega, zvočnega ter videogradiva.
Spodaj prikazane informacije so s tamkajšnje opisne strani.

Ta slika je bila naložena v formatu JPEG, čeprav sestoji iz nefotografskih podatkov. Te informacije bi bile bolj učinkovito ali natančno shranjene v formatu PNG ali SVG. Če je mogoče, naložite različico PNG ali SVG te slike brez artefaktov stiskanja, izpeljanih iz ne-JPEG vira (ali z odstranjenimi obstoječimi artefakti). Ko boste to storili, označite JPEG različico z {{Superseded|NewImage.ext}} in to oznako odstranite.. Ta oznaka naj se ne uporablja za fotografije ali preslikave. Za več informacij glejte {{BadJPEG}}.
Opis Brownian Motion on a Sphere. The generator of ths process is ½ times the Laplace-Beltrami-Operator
Datum poletje 2007
date QS:P,+2007-00-00T00:00:00Z/9,P4241,Q40720564
(blender file as of 28.06.2007)
Vir read some papers (eg Price, Gareth C.; Williams, David: "Rolling with “slipping”" : I. Séminaire de probabilités de Strasbourg, 17 (1983), p. 194-197 You can download it from http://www.numdam.org/item?id=SPS_1983__17__194_0) use the GNU R code and the python code (in blender3d) to create this image.
Avtor Thomas Steiner
Dovoljenje
(Nadaljnja uporaba datoteke)		 Thomas Steiner put it under the CC-by-SA 2.5. If you use the python code or the R code, please give a reference to Christian Bayer and Thomas Steiner.
 
Ta slika je bila ustvarjena z Blender.
w:sl:Creative Commons
priznanje avtorstva deljenje pod enakimi pogoji
Datoteka je objavljena pod licenco Creative Commons Priznanje avtorstva-Deljenje pod enakimi pogoji 2.5 Generična.
Dovoljeno vam je:
  • deljenje – reproducirati, distribuirati in javno priobčevati delo
  • predelava – predelati delo
Pod naslednjimi pogoji:
  • priznanje avtorstva – Navesti morate ustrezno avtorstvo, povezavo do licence in morebitne spremembe. To lahko storite na kakršen koli primeren način, vendar ne na način, ki bi nakazoval, da dajalec licence podpira vas ali vašo uporabo dela.
  • deljenje pod enakimi pogoji – Če boste to vsebino predelali, preoblikovali ali uporabili kot izhodišče za drugo delo, morate svoj prispevek distribuirati pod enako ali združljivo licenco, kot jo ima izvirnik.

code

Perhaps you grab the source from the "edit" page without the wikiformating.

GNU R

This creates the paths and saves them into textfiles that can be read by blender. There are also paths for BMs on a torus. 

# calculate a Brownian motion on the sphere; the output is a list
# consisting of:
# Z ... BM on the sphere
# Y ... tangential BM, see Price&Williams
# b ... independent 1D BM (see Price & Williams)
# B ... generating 3D BM
# n ... number of time-steps in the discretization
# T ... the above processes are given on a uniform mesh of size
#       n on [0,T]
euler = function(x0, T, n) {
  # initialize objects
  dt = T/(n-1);
  dB = matrix(rep(0,3*(n-1)),ncol=3, nrow=n-1);
  dB[,1] = rnorm(n-1, 0, sqrt(dt));
  dB[,2] = rnorm(n-1, 0, sqrt(dt));
  dB[,3] = rnorm(n-1, 0, sqrt(dt));
  Z = matrix(rep(0,3*n), ncol=3, nrow=n);
  dZ = matrix(rep(0,3*(n-1)), ncol=3, nrow=n-1);
  Y = matrix(rep(0,3*n), ncol=3, nrow=n);
  B = matrix(rep(0,3*n), ncol=3, nrow=n);
  b = rep(0, n);
  Z[1,] = x0;

  #do the computation
  for(k in 2:n){
    B[k,] = B[k-1,] + dB[k-1,];
    dZ[k-1,] = cross(Z[k-1,],dB[k-1,]) - Z[k-1,]*dt;
    Z[k,] = Z[k-1,] + dZ[k-1,];
    Y[k,] = Y[k-1,] - cross(Z[k-1,],dZ[k-1,]);
    b[k] = b[k-1] + dot(Z[k-1,],dB[k-1,]);
  }
  return(list(Z = Z, Y = Y, b = b, B = B, n = n, T = T));
}

# write the output from euler in csv-files
euler.write = function(bms, files=c("Z.csv","Y.csv","b.csv","B.csv"),steps=bms$n){
  bigsteps=round(seq(1,bms$n,length=steps))
  write.table(bms$Z[bigsteps,],file=files[1],col.names=F,row.names=F,sep=",",dec=".");
  write.table(bms$Y[bigsteps,],file=files[2],col.names=F,row.names=F,sep=",",dec=".");
  write.table(bms$b[bigsteps],file=files[3],col.names=F,row.names=F,sep=",",dec=".");
  write.table(bms$B[bigsteps,],file=files[4],col.names=F,row.names=F,sep=",",dec=".");
}

# calculate a Brownian motion on a 3-d torus with outer
# radius R and inner radius r
eulerTorus = function(x0, r, R, t, n) {
  # initialize objects
  dt = t/(n-1);
  dB = matrix(rep(0,3*(n-1)),ncol=3, nrow=n-1);
  dB[,1] = rnorm(n-1, 0, sqrt(dt));
  dB[,2] = rnorm(n-1, 0, sqrt(dt));
  dB[,3] = rnorm(n-1, 0, sqrt(dt));
  Z = matrix(rep(0,3*n), ncol=3, nrow=n);
  B = matrix(rep(0,3*n), ncol=3, nrow=n);
  dZ = matrix(rep(0,3*(n-1)), ncol=3, nrow=n-1);
  Z[1,] = x0;
  nT = rep(0,3);

  #do the computation
  for(k in 2:n){
    B[k,] = B[k-1,] + dB[k-1,];
    nT = nTorus(Z[k-1,],r,R);
    dZ[k-1,] = cross(nT, dB[k-1,]) + HTorus(Z[k-1,],r,R)*nT*dt;
    Z[k,] = Z[k-1,] + dZ[k-1,];
  }
  return(list(Z = Z, B = B, n = n, t = t));
}

# write the output from euler in csv-files
torus.write = function(bmt, files=c("tZ.csv","tB.csv"),steps=bmt$n){
  bigsteps=round(seq(1,bmt$n,length=steps))
  write.table(bmt$Z[bigsteps,],file=files[1],col.names=F,row.names=F,sep=",",dec=".");
  write.table(bmt$B[bigsteps,],file=files[2],col.names=F,row.names=F,sep=",",dec=".");
}

# "defining" function of a torus
fTorus = function(x,r,R){
  return((x[1]^2+x[2]^2+x[3]^2+R^2-r^2)^2 - 4*R^2*(x[1]^2+x[2]^2));
}

# normal vector of a 3-d torus with outer radius R and inner radius r
nTorus = function(x, r, R) {
  c1 = x[1]*(x[1]^2+x[2]^2+x[3]^2-R^2-r^2)/(3*x[1]^4*x[2]^2+3*x[3]^4*x[2]^2
    +3*x[3]^4*x[1]^2+6*x[3]^2*x[1]^2*x[2]^2+3*x[1]^2*x[2]^4+3*x[3]^2*x[2]^4
    -2*x[3]^2*R^2*r^2-4*x[1]^2*x[2]^2*R^2+x[1]^6+x[2]^6+x[3]^6+3*x[3]^2*x[1]^4
    -4*x[1]^2*x[2]^2*r^2-4*x[1]^2*x[3]^2*r^2+2*R^2*x[1]^2*r^2
    -4*x[2]^2*x[3]^2*r^2+2*R^2*x[2]^2*r^2-2*x[1]^4*R^2-2*x[1]^4*r^2
    +R^4*x[1]^2+x[1]^2*r^4-2*x[2]^4*R^2-2*x[2]^4*r^2+R^4*x[2]^2+x[2]^2*r^4
    +x[3]^2*R^4+x[3]^2*r^4-2*x[3]^4*r^2+2*x[3]^4*R^2)^(1/2);
  c2 = x[2]*(x[1]^2+x[2]^2+x[3]^2-R^2-r^2)/(3*x[1]^4*x[2]^2+3*x[3]^4*x[2]^2
    +3*x[3]^4*x[1]^2+6*x[3]^2*x[1]^2*x[2]^2+3*x[1]^2*x[2]^4+3*x[3]^2*x[2]^4
    -2*x[3]^2*R^2*r^2-4*x[1]^2*x[2]^2*R^2+x[1]^6+x[2]^6+x[3]^6
    +3*x[3]^2*x[1]^4-4*x[1]^2*x[2]^2*r^2-4*x[1]^2*x[3]^2*r^2+2*R^2*x[1]^2*r^2
    -4*x[2]^2*x[3]^2*r^2+2*R^2*x[2]^2*r^2-2*x[1]^4*R^2-2*x[1]^4*r^2+R^4*x[1]^2
    +x[1]^2*r^4-2*x[2]^4*R^2-2*x[2]^4*r^2+R^4*x[2]^2+x[2]^2*r^4+x[3]^2*R^4
    +x[3]^2*r^4-2*x[3]^4*r^2+2*x[3]^4*R^2)^(1/2);
  c3 = (x[1]^2+x[2]^2+x[3]^2+R^2-r^2)*x[3]/(3*x[1]^4*x[2]^2+3*x[3]^4*x[2]^2
                                            +3*x[3]^4*x[1]^2
                                            +6*x[3]^2*x[1]^2*x[2]^2
                                            +3*x[1]^2*x[2]^4+3*x[3]^2*x[2]^4
                                            -2*x[3]^2*R^2*r^2
                                            -4*x[1]^2*x[2]^2*R^2+x[1]^6
                                            +x[2]^6+x[3]^6+3*x[3]^2*x[1]^4
                                            -4*x[1]^2*x[2]^2*r^2
                                            -4*x[1]^2*x[3]^2*r^2
                                            +2*R^2*x[1]^2*r^2
                                            -4*x[2]^2*x[3]^2*r^2
                                            +2*R^2*x[2]^2*r^2-2*x[1]^4*R^2
                                            -2*x[1]^4*r^2+R^4*x[1]^2
                                            +x[1]^2*r^4-2*x[2]^4*R^2
                                            -2*x[2]^4*r^2+R^4*x[2]^2
                                            +x[2]^2*r^4+x[3]^2*R^4
                                            +x[3]^2*r^4-2*x[3]^4*r^2
                                            +2*x[3]^4*R^2)^(1/2);
  return(c(c1,c2,c3));
}

# mean curvature of a 3-d torus with outer radius R and inner radius r
HTorus = function(x, r, R){
  return( -(3*x[1]^4*r^4+4*x[2]^6*x[3]^2+4*x[1]^6*x[2]^2-3*x[2]^4*x[3]^2*R^2
            -2*x[1]^6*R^2+4*x[1]^2*x[3]^6+x[3]^6*R^2+4*x[2]^4*R^2*r^2-x[1]^2*r^6
            -x[2]^2*r^6+x[2]^4*R^4+4*x[2]^2*x[3]^2*R^4+6*x[2]^2*x[3]^2*r^4
            -2*x[1]^2*R^2*r^4-x[1]^2*R^4*r^2-9*x[1]^4*x[2]^2*r^2
            -9*x[1]^4*x[3]^2*r^2+4*x[1]^4*R^2*r^2+12*x[1]^2*x[3]^4*x[2]^2
            -3*x[2]^6*r^2+4*x[1]^6*x[3]^2+3*x[3]^4*r^4-x[3]^4*R^4
            -9*x[2]^4*x[3]^2*r^2+2*x[2]^2*x[3]^2*R^2*r^2+4*x[1]^2*x[2]^6
            -6*x[1]^2*x[3]^2*x[2]^2*R^2-x[3]^2*r^6+6*x[2]^4*x[3]^4+x[3]^8
            +x[1]^8+x[2]^8-3*x[1]^6*r^2+6*x[1]^4*x[3]^4+12*x[1]^2*x[3]^2*x[2]^4
            -6*x[1]^2*x[2]^4*R^2-2*x[3]^4*R^2*r^2-2*x[2]^2*R^2*r^4-x[2]^2*R^4*r^2
            -9*x[2]^2*x[3]^4*r^2+x[3]^2*R^2*r^4+x[3]^2*R^4*r^2-9*x[1]^2*x[2]^4*r^2
            +2*x[1]^2*R^4*x[2]^2+6*x[1]^2*x[2]^2*r^4-3*x[1]^4*x[3]^2*R^2
            -6*x[1]^4*x[2]^2*R^2+4*x[1]^2*x[3]^2*R^4+6*x[1]^2*x[3]^2*r^4
            -9*x[1]^2*x[3]^4*r^2+8*x[1]^2*R^2*x[2]^2*r^2+2*x[1]^2*x[3]^2*R^2*r^2
            +x[1]^4*R^4-3*x[3]^6*r^2-2*x[2]^6*R^2+6*x[1]^4*x[2]^4-x[3]^2*R^6
            -18*x[1]^2*x[2]^2*x[3]^2*r^2+4*x[2]^2*x[3]^6+12*x[1]^4*x[3]^2*x[2]^2
            +3*x[2]^4*r^4)/(3*x[1]^4*x[2]^2+3*x[3]^4*x[2]^2+3*x[3]^4*x[1]^2
                            +6*x[3]^2*x[1]^2*x[2]^2+3*x[1]^2*x[2]^4+3*x[3]^2*x[2]^4
                            -2*x[3]^2*R^2*r^2-4*x[1]^2*x[2]^2*R^2+x[1]^6+x[2]^6
                            +x[3]^6+3*x[3]^2*x[1]^4-4*x[1]^2*x[2]^2*r^2
                            -4*x[1]^2*x[3]^2*r^2+2*R^2*x[1]^2*r^2
                            -4*x[2]^2*x[3]^2*r^2+2*R^2*x[2]^2*r^2-2*x[1]^4*R^2
                            -2*x[1]^4*r^2+R^4*x[1]^2+x[1]^2*r^4-2*x[2]^4*R^2
                            -2*x[2]^4*r^2+R^4*x[2]^2+x[2]^2*r^4+x[3]^2*R^4
                            +x[3]^2*r^4-2*x[3]^4*r^2+2*x[3]^4*R^2)^(3/2));
}

# calculate the cross product of the two 3-dim vectors
# x and y. No argument-checking for performance reasons
cross = function(x,y){
  res = rep(0,3);
  res[1] = x[2]*y[3] - x[3]*y[2];
  res[2] = -x[1]*y[3] + x[3]*y[1];
  res[3] = x[1]*y[2] - x[2]*y[1];
  return(res);
}

# calculate the inner product of two vectors of dim 3
# returns a number, not a 1x1-matrix!
dot = function(x,y){
  return(sum(x*y));
}

# calculate the cross product of the two 3-dim vectors
# x and y. No argument-checking for performance reasons
cross = function(x,y){
  res = rep(0,3);
  res[1] = x[2]*y[3] - x[3]*y[2];
  res[2] = -x[1]*y[3] + x[3]*y[1];
  res[3] = x[1]*y[2] - x[2]*y[1];
  return(res);
}

#############
### main-teil
set.seed(280180)
et=eulerTorus(c(3,0,0),3,5,19,10000)
torus.write(et,steps=9000)
#
#bms=euler(c(1,0,0),4,70000)
#euler.write(bms,steps=10000)

blender3d

The blender (python) code to create a image that looks almost like this one. Play around... 

## import data from matlab-text-file and draw BM on the S^2

## (c) 2007 by Christan Bayer and Thomas Steiner

from Blender import Curve, Object, Scene, Window, BezTriple, Mesh, Material, Camera,
World
from math import *

##import der BM auf der Kugel aus einem csv-file
def importcurve(inpath="Z.csv"):
        infile = open(inpath,'r')
        lines = infile.readlines()
        vec=[]
        for i in lines:
                li=i.split(',')
                vec.append([float(li[0]),float(li[1]),float(li[2].strip())])
        infile.close()
        return(vec)

##function um aus einem vektor (mit den x,y,z Koordinaten) eine Kurve zu machen
def vec2Cur(curPts,name="BMonSphere"):
        bztr=[]
        bztr.append(BezTriple.New(curPts[0]))
        bztr[0].handleTypes=(BezTriple.HandleTypes.VECT,BezTriple.HandleTypes.VECT)
        cur=Curve.New(name) ##TODO wenn es das Objekt schon gibt, dann nicht neu erzeugen
        cur.appendNurb(bztr[0])
        for i in range(1,len(curPts)):
                bztr.append(BezTriple.New(curPts[i]))
                bztr[i].handleTypes=(BezTriple.HandleTypes.VECT,BezTriple.HandleTypes.VECT)
                cur[0].append(bztr[i])
        return( cur )

#erzeugt einen kreis, der später die BM umgibt (liegt in y-z-Ebene)
def circle(r,name="tubus"):
        bzcir=[]
        bzcir.append(BezTriple.New(0.,-r,-4./3.*r, 0.,-r,0., 0.,-r,4./3.*r))
        bzcir[0].handleTypes=(BezTriple.HandleTypes.FREE,BezTriple.HandleTypes.FREE)
        cur=Curve.New(name) ##TODO wenn es das Objekt schon gibt, dann nicht neu erzeugen
        cur.appendNurb(bzcir[0])
        #jetzt alle weietren pkte
        bzcir.append(BezTriple.New(0.,r,4./3.*r, 0.,r,0., 0.,r,-4./3.*r))
        bzcir[1].handleTypes=(BezTriple.HandleTypes.FREE,BezTriple.HandleTypes.FREE)
        cur[0].append(bzcir[1])
        bzcir.append(BezTriple.New(0.,-r,-4./3.*r, 0.,-r,0., 0.,-r,4./3.*r))
        bzcir[2].handleTypes=(BezTriple.HandleTypes.FREE,BezTriple.HandleTypes.FREE)
        cur[0].append(bzcir[2])
        return ( cur )

#erzeuge mit skript eine (glas)kugel (UVSphere)
def sphGlass(r=1.0,name="Glaskugel",n=40,smooth=0):
        glass=Mesh.New(name) ##TODO wenn es das Objekt schon gibt, dann nicht neu erzeugen
        for i in range(0,n):
                for j in range(0,n):
                        x=sin(j*pi*2.0/(n-1))*cos(-pi/2.0+i*pi/(n-1))*1.0*r
                        y=cos(j*pi*2.0/(n-1))*(cos(-pi/2.0+i*pi/(n-1)))*1.0*r
                        z=sin(-pi/2.0+i*pi/(n-1))*1.0*r
                        glass.verts.extend(x,y,z)
        for i in range(0,n-1): 
                for j in range(0,n-1):
                        glass.faces.extend([i*n+j,i*n+j+1,(i+1)*n+j+1,(i+1)*n+j])
                        glass.faces[i*(n-1)+j].smooth=1
        return( glass )

def torus(r=0.3,R=1.4): 
        krGro=circle(r=R,name="grTorusKreis")
        

#jetzt das material ändern
def verglasen(mesh):
        matGlass = Material.New("glas") ##TODO wenn es das Objekt schon gibt, dann nicht
neu erzeugen
        #matGlass.setSpecShader(0.6)
        matGlass.setHardness(30) #für spec: 30
        matGlass.setRayMirr(0.15)
        matGlass.setFresnelMirr(4.9)
        matGlass.setFresnelMirrFac(1.8)
        matGlass.setIOR(1.52)
        matGlass.setFresnelTrans(3.9)
        matGlass.setSpecTransp(2.7)
        #glass.materials.setSpecTransp(1.0)
        matGlass.rgbCol = [0.66, 0.81, 0.85]
        matGlass.mode |= Material.Modes.ZTRANSP
        matGlass.mode |= Material.Modes.RAYTRANSP
        #matGlass.mode |= Material.Modes.RAYMIRROR
        mesh.materials=[matGlass]
        return ( mesh )

def maleBM(mesh):
        matDraht = Material.New("roterDraht") ##TODO wenn es das Objekt schon gibt, dann
nicht neu erzeugen
        matDraht.rgbCol = [1.0, 0.1, 0.1]
        mesh.materials=[matDraht]
        return( mesh )

#eine solide Mesh-Ebene (Quader)
# auf der höhe ebh, dicke d, seitenlänge (quadratisch) 2*gr
def ebene(ebh=-2.5,d=0.1,gr=6.0,name="Schattenebene"):
        quader=Mesh.New(name) ##TODO wenn es das Objekt schon gibt, dann nicht neu erzeugen
        #obere ebene
        quader.verts.extend(gr,gr,ebh)
        quader.verts.extend(-gr,gr,ebh)
        quader.verts.extend(-gr,-gr,ebh)
        quader.verts.extend(gr,-gr,ebh)
        #untere ebene
        quader.verts.extend(gr,gr,ebh-d)
        quader.verts.extend(-gr,gr,ebh-d)
        quader.verts.extend(-gr,-gr,ebh-d)
        quader.verts.extend(gr,-gr,ebh-d)
        quader.faces.extend([0,1,2,3])
        quader.faces.extend([0,4,5,1])
        quader.faces.extend([1,5,6,2])
        quader.faces.extend([2,6,7,3])
        quader.faces.extend([3,7,4,0])
        quader.faces.extend([4,7,6,5])
        #die ebene einfärben
        matEb = Material.New("ebenen_material") ##TODO wenn es das Objekt schon gibt, dann
nicht neu erzeugen
        matEb.rgbCol = [0.53, 0.51, 0.31]
        matEb.mode |= Material.Modes.TRANSPSHADOW
        matEb.mode |= Material.Modes.ZTRANSP
        quader.materials=[matEb]
        return (quader)

###################
#### main-teil ####

# wechsel in den edit-mode
editmode = Window.EditMode()
if editmode: Window.EditMode(0)

dataBMS=importcurve("C:/Dokumente und Einstellungen/thire/Desktop/bmsphere/Z.csv")
#dataBMS=importcurve("H:\MyDocs\sphere\Z.csv")
BMScur=vec2Cur(dataBMS,"BMname")
#dataStereo=importcurve("H:\MyDocs\sphere\stZ.csv")
#stereoCur=vec2Cur(dataStereo,"SterName")

cir=circle(r=0.01)

glass=sphGlass()
glass=verglasen(glass)
ebe=ebene()

#jetzt alles hinzufügen
scn=Scene.GetCurrent()
obBMScur=scn.objects.new(BMScur,"BMonSphere")
obcir=scn.objects.new(cir,"round")
obgla=scn.objects.new(glass,"Glaskugel")
obebe=scn.objects.new(ebe,"Ebene")
#obStereo=scn.objects.new(stereoCur,"StereoCurObj")

BMScur.setBevOb(obcir)
BMScur.update()
BMScur=maleBM(BMScur)

#stereoCur.setBevOb(obcir)
#stereoCur.update()

cam = Object.Get("Camera") 
#cam.setLocation(-5., 5.5, 2.9) 
#cam.setEuler(62.0,-1.,222.6)
#alternativ, besser??
cam.setLocation(-3.3, 8.4, 1.7) 
cam.setEuler(74,0,200)

world=World.GetCurrent()
world.setZen([0.81,0.82,0.61])
world.setHor([0.77,0.85,0.66])

if editmode: Window.EditMode(1)  # optional, zurück n den letzten modus

        
#ergebnis von
#set.seed(24112000)
#sbm=euler(c(0,0,-1),T=1.5,n=5000)
#euler.write(sbm)

Napisi

Dodajte enovrstični opis, kaj ta datoteka predstavlja
Brownian Motion on a Sphere, as a process generated by the Laplace-Beltrami-Operator

Predmeti, prikazani v tej datoteki

motiv

tip MIME

image/jpeg

kontrolna vsota

f51c8d9194ca77a5c2a7d77d21c292e592d5c6c5

način določitve: SHA-1 angleščina

višina

356 piksel

širina

365 piksel

Zgodovina datoteke

Kliknite datum in čas za ogled datoteke, ki je bila takrat naložena.

Datum in časSličicaVelikostUporabnikKomentar
trenutno21:53, 22. december 2013Sličica za različico z datumom 21:53, 22. december 2013365 × 356 (10 KB)Olli NiemitaloCropped (in a JPEG-lossless way)
00:53, 29. september 2007Sličica za različico z datumom 00:53, 29. september 2007783 × 588 (14 KB)Thire{{Information |Description = Brownian Motion on a Sphere |Source = read some papere ;) use the GNU R code and the python code (in blender3d) to create this image. |Date = summer 2007 (blender file as of ) |Author = Thomas Steiner |P

Datoteka je del naslednje 1 strani slovenske Wikipedije (strani drugih projektov niso navedene):

Globalna uporaba datoteke

To datoteko uporabljajo tudi naslednji vikiji:

Pridobljeno iz »https://sl.wikipedia.org/wiki/Slika:BMonSphere.jpg«