KochanekBartels: Kochanek-Bartels quaternions spline
In qsplines: Quaternions Splines

View source: R/KochanekBartels.R

KochanekBartels

R Documentation

Kochanek-Bartels quaternions spline

Description

Constructs a quaternions spline by the Kochanek-Bartels algorithm.

Usage

KochanekBartels(
  keyRotors,
  keyTimes = NULL,
  tcb = c(0, 0, 0),
  times,
  n_intertimes,
  endcondition = "natural",
  constantSpeed = FALSE
)

Arguments

`keyRotors`	a vector of unit quaternions (rotors) to be interpolated
`keyTimes`	the times corresponding to the key rotors; must be an increasing vector of the same length a `keyRotors` if `endcondition = "natural"` or of length one more than number of key rotors if `endcondition = "closed"`
`tcb`	a vector of three numbers respectively corresponding to tension, continuity and bias
`times`	the times of interpolation; each time must lie within the range of the key times; this parameter can be missing if `keyTimes` is `NULL` and `n_intertimes` is not missing, and it is ignored if `constantSpeed=TRUE`
`n_intertimes`	if given, this argument has precedence over `times`; `keyTimes` can be `NULL` and `times` is constructed by linearly interpolating the key times such that there are `n_intertimes - 1` between two key times (so the times are the key times if `n_intertimes = 1`)
`endcondition`	start/end conditions, can be `"closed"` or `"natural"`
`constantSpeed`	Boolean, whether to re-parameterize the spline to have constant speed; in this case, `"times"` is ignored and you must set the interpolating times with the help of `n_intertimes`

Value

A vector of quaternions having the same length as the times vector.

Examples

library(qsplines)
# Using a Kochanek-Bartels quaternions spline to construct 
#   a spherical curve interpolating some key points on the 
#     sphere of radius 5
    
# helper function: spherical to Cartesian coordinates
sph2cart <- function(rho, theta, phi){
  return(c(
    rho * cos(theta) * sin(phi),
    rho * sin(theta) * sin(phi),
    rho * cos(phi)
  ))
}

# construction of the key points on the sphere
keyPoints <- matrix(nrow = 0L, ncol = 3L)
theta_ <- seq(0, 2*pi, length.out = 9L)[-1L]
phi <- 1.3
for(theta in theta_){
  keyPoints <- rbind(keyPoints, sph2cart(5, theta, phi))
  phi = pi - phi
}
n_keyPoints <- nrow(keyPoints)

# construction of the key rotors; the first key rotor 
#   is the identity quaternion and rotor i sends the 
#     first key point to the i-th key point
keyRotors <- quaternion(length.out = n_keyPoints)
rotor <- keyRotors[1L] <- H1
for(i in seq_len(n_keyPoints - 1L)){
  keyRotors[i+1L] <- rotor <-
    quaternionFromTo(
      keyPoints[i, ]/5, keyPoints[i+1L, ]/5
    ) * rotor
}

# Kochanek-Bartels quaternions spline
rotors <- KochanekBartels(
  keyRotors, n_intertimes = 25L, 
  endcondition = "closed", tcb = c(-1, 5, 0)
)

# construction of the interpolating points on the sphere
points <- matrix(nrow = 0L, ncol = 3L)
keyPoint1 <- rbind(keyPoints[1L, ])
for(i in seq_along(rotors)){
  points <- rbind(points, rotate(keyPoint1, rotors[i]))
}

# visualize the result with the 'rgl' package
library(rgl)
spheres3d(0, 0, 0, radius = 5, color = "lightgreen")
spheres3d(points, radius = 0.2, color = "midnightblue")
spheres3d(keyPoints, radius = 0.25, color = "red")

qsplines documentation built on March 7, 2023, 7:41 p.m.