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Recall that a Hopf torus is a two-dimensional object in the 4D space defined by a profile curve: a closed curve on the unit sphere. When mapping it to the 3D space with the stereographic projection, we can obtain a beautiful object, or an ugly one, depending on the choice of the profile curve.
Here, we will see the Hopf torus defined by this profile curve:
This is the intersection of the unit sphere with a cubical cone, the isosurface of equation \(x^2 + y^2 + z^2 = 0\). First, I obtained a mesh of this surface thanks to the rmarchingcubes package:
library(rgl) library(rmarchingcubes) # cubical cone #### f <- function(x, y, z) { x^3 + y^3 + z^3 } x_ <- y_ <- z_ <- seq(-1.05, 1.05, length.out = 150L) Grid <- expand.grid(X = x_, Y = y_, Z = z_) voxel <- array(with(Grid, f(X, Y, Z)), dim = c(150L, 150L, 150L)) surf <- contour3d(voxel, level = 0, x_, y_, z_) coneMesh <- tmesh3d( vertices = t(surf[["vertices"]]), indices = t(surf[["triangles"]]), normals = surf[["normals"]] )
Then I obtained the intersection with the unit sphere thanks to the
clipMesh3d
and getBoundary3d
functions of the
rgl package:
# intersection with unit sphere #### sphereMesh <- Rvcg::vcgSphere(subdivision = 5L) mesh <- clipMesh3d( sphereMesh, fn = f, minVertices = 20000L ) boundary <- getBoundary3d(mesh, sorted = TRUE, color = "black", lwd = 2) # plot #### open3d(windowRect = 50 + c(0, 0, 512, 512), zoom = 0.9) shade3d(coneMesh, color = "red", alpha = 0.5, polygon_offset = 1) shade3d(sphereMesh, color = "blue", alpha = 0.5, polygon_offset = 1) shade3d(boundary)
The curve has not the required orientation of a nice profile curve. Its
axis of symmetry is directed by
\((1,1,1)\), and we need
\((0,0,1)\) instead. So one has to
rotate the curve. To do so, I use an exported function from the
cgalMeshes package, namely
quaternionFromTo
. It will return a unit quaternion
corresponding to the desired rotation. I already talked about this way
to obtain a rotation sending a given vector to another given vector,
here.
# get points at the intersection and rotate them #### pts <- boundary[["vb"]][-4L, boundary[["is"]][1L, ]] q <- cgalMeshes:::quaternionFromTo(c(1, 1, 1)/sqrt(3), c(0, 0, 1)) R <- onion::as.orthogonal(q) gamma0 <- t(R %*% pts)[, c(3L, 2L, 1L)]
Now let’s introduce a function which creates a mesh of the Hopf torus
defined by a discretized curve, such as our matrix of points
gamma0
. Again, I use an exported function from
cgalMeshes, namely meshTopology
, which
returns the incidences between the vertices of the mesh.
# Hopf torus mesh from a discrete curve `gamma` #### hMesh <- function(gamma, m) { nu <- nrow(gamma) uperiodic <- TRUE u_ <- 1L:nu vperiodic <- TRUE nv <- as.integer(m) v_ <- 1L:nv R <- array(NA_real_, dim = c(3L, nv, nu)) for(k in 1L:nv) { K <- k - 1L cosphi <- cospi(2*K/m) sinphi <- sinpi(2*K/m) for(j in 1L:nu) { p1 <- gamma[j, 1L] p2 <- gamma[j, 2L] p3 <- gamma[j, 3L] yden <- sqrt(2 * (1 + p1)) y1 <- (1 + p1) / yden y2 <- p2 / yden y3 <- p3 / yden x1 <- cosphi * y3 + sinphi * y2 x2 <- cosphi * y2 - sinphi * y3 x3 <- sinphi * y1 x4 <- cosphi * y1 R[, k, j] <- c(x1, x2, x3)/(1 - x4) } } vs <- matrix(R, nrow = 3L, ncol = nu*nv) tris <- cgalMeshes:::meshTopology(nu, nv, uperiodic, vperiodic) tmesh3d( vertices = vs, indices = tris, homogeneous = FALSE ) }
If you run hMesh(gamma0, m)
with m
large
enough, here is the mesh you will obtain (actually you have to close
gamma0
, that is to say you have to use
rbind(gamma0, gamma0[1L, ])
):
Finally I did another animation. The Hopf torus whose profile curve is
the equator of the unit sphere is nothing but an ordinary torus after
the stereographic projection. Then, I scaled the
\(x\)-coordinates of
gamma0
continuously from a factor zero to a positive factor
and I plotted the (stereographic projection of the) Hopf torus
corresponding to each scaling. In this way the ordinary torus is
smoothly transformed to the previous Hopf torus:
The code:
h_ <- seq(0, 2, length.out = 60L) # scaling factors open3d(windowRect = 50 + c(0, 0, 512, 512)) bg3d(rgb(54, 57, 64, maxColorValue = 255)) view3d(0, 0, zoom = 0.75) for(i in seq_along(h_)) { gamma <- gamma0 gamma[, 1L] <- h_[i] * gamma[, 1L] # normalize so that the points are on the sphere gamma <- gamma / sqrt(apply(gamma, 1L, crossprod)) gamma <- rbind(gamma, gamma[1L, ]) mesh <- hMesh(gamma, 500L) mesh <- addNormals(mesh, angleWeighted = FALSE) shade3d(mesh, color = "firebrick4") snapshot3d(sprintf("zzpic%03d.png", i), webshot = FALSE) clear3d() } # mount the animation #### library(gifski) pngFiles <- Sys.glob("zzpic*.png") gifski( png_files = pngFiles, gif_file = "HopfTorusCubicalConeToTorus.gif", width = 512, height = 512, delay = 1/15 ) file.remove(pngFiles)
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