Nothing
inst/doc/shape.R
In shape: Functions for Plotting Graphical Shapes, Colors
### R code from vignette source 'shape.Rnw'
###################################################
### code chunk number 1: preliminaries
###################################################
library("shape")
options(prompt = "> ")
options(width=90)
###################################################
### code chunk number 2: s1
###################################################
par(mfrow = c(2, 2))
image(matrix(nrow = 1, ncol = 50, data = 1:50),
main = "intpalette",
col = intpalette(c("red", "blue", "yellow", "green", "black"),
numcol = 50))
#
shadepalette(n = 10, "white", "black")
#
image(matrix(nrow = 1, ncol = 50, data = 1:50),
col = shadepalette(50, "red", "blue"),
main = "shadepalette")
#
par(mar = c(0, 0, 0, 0))
persp(volcano, theta = 135, phi = 30, col = drapecol(volcano),
main = "drapecol", border = NA)
###################################################
### code chunk number 3: s1
###################################################
par(mfrow = c(2, 2))
image(matrix(nrow = 1, ncol = 50, data = 1:50),
main = "intpalette",
col = intpalette(c("red", "blue", "yellow", "green", "black"),
numcol = 50))
#
shadepalette(n = 10, "white", "black")
#
image(matrix(nrow = 1, ncol = 50, data = 1:50),
col = shadepalette(50, "red", "blue"),
main = "shadepalette")
#
par(mar = c(0, 0, 0, 0))
persp(volcano, theta = 135, phi = 30, col = drapecol(volcano),
main = "drapecol", border = NA)
###################################################
### code chunk number 4: s2
###################################################
par(mfrow = c(2, 2), mar = c(3, 3, 3, 3))
#
# rotating points on a line
#
xy <- matrix(ncol = 2, data = c(1:5, rep(1, 5)))
plot(xy, xlim = c(-6, 6), ylim = c(-6, 6), type = "b",
pch = 16, main = "rotatexy", col = 1)
for (i in 1:5)
points(rotatexy(xy, mid = c(0, 0), angle = 60*i),
col = i+1, type = "b", pch = 16)
points(0, 0, cex = 2, pch = 22, bg = "black")
legend("topright", legend = 60*(0:5), col = 1:6, pch = 16,
title = "angle")
legend("topleft", legend = "midpoint", pt.bg = "black",
pt.cex = 2, pch = 22, box.lty = 0)
#
# rotating lines..
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x)
cols <- intpalette(c("blue", "green", "yellow", "red"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-3, 3), main = "rotatexy",
col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i), col = cols[i], lwd = 2)
#
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x*2)
cols <- intpalette(c("red", "yellow", "black"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-4, 5), main = "rotatexy,
asp = TRUE", col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i, asp = TRUE),
col = cols[i], lwd = 2)
#
# rotating points
#
cols <- femmecol(500)
plot(x, y, xlim = c(-1, 1), ylim = c(-1, 1), main = "rotatexy",
col = cols[1], type = "n")
for (i in 2:500) {
xy <- rotatexy(c(0, 1), angle = 0.72*i, mid = c(0, 0))
points(xy[1], xy[2], col = cols[i], pch = ".", cex = 2)
}
###################################################
### code chunk number 5: s2
###################################################
par(mfrow = c(2, 2), mar = c(3, 3, 3, 3))
#
# rotating points on a line
#
xy <- matrix(ncol = 2, data = c(1:5, rep(1, 5)))
plot(xy, xlim = c(-6, 6), ylim = c(-6, 6), type = "b",
pch = 16, main = "rotatexy", col = 1)
for (i in 1:5)
points(rotatexy(xy, mid = c(0, 0), angle = 60*i),
col = i+1, type = "b", pch = 16)
points(0, 0, cex = 2, pch = 22, bg = "black")
legend("topright", legend = 60*(0:5), col = 1:6, pch = 16,
title = "angle")
legend("topleft", legend = "midpoint", pt.bg = "black",
pt.cex = 2, pch = 22, box.lty = 0)
#
# rotating lines..
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x)
cols <- intpalette(c("blue", "green", "yellow", "red"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-3, 3), main = "rotatexy",
col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i), col = cols[i], lwd = 2)
#
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x*2)
cols <- intpalette(c("red", "yellow", "black"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-4, 5), main = "rotatexy,
asp = TRUE", col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i, asp = TRUE),
col = cols[i], lwd = 2)
#
# rotating points
#
cols <- femmecol(500)
plot(x, y, xlim = c(-1, 1), ylim = c(-1, 1), main = "rotatexy",
col = cols[1], type = "n")
for (i in 2:500) {
xy <- rotatexy(c(0, 1), angle = 0.72*i, mid = c(0, 0))
points(xy[1], xy[2], col = cols[i], pch = ".", cex = 2)
}
###################################################
### code chunk number 6: s3
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
emptyplot(c(-1, 1))
col <- c(rev(greycol(n = 30)), greycol(30))
filledellipse(rx1 = 1, rx2 = 0.5, dr = 0.1, col = col)
title("filledellipse")
#
emptyplot(c(-1, 1), c(-1, 1))
filledellipse(col = col, dr = 0.1)
title("filledellipse")
#
color <-gray(seq(1, 0.3, length.out = 30))
emptyplot(xlim = c(-2, 2), ylim = c(-2, 2), col = color[length(color)])
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = -45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 0, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 90, dr = 0.1)
title("filledellipse")
#
emptyplot(main = "getellipse")
col <-femmecol(90)
for (i in seq(0, 180, by = 2))
lines(getellipse(0.5, 0.25, mid = c(0.5, 0.5), angle = i, dr = 0.1),
type = "l", col = col[(i/2)+1], lwd = 2)
###################################################
### code chunk number 7: s3
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
emptyplot(c(-1, 1))
col <- c(rev(greycol(n = 30)), greycol(30))
filledellipse(rx1 = 1, rx2 = 0.5, dr = 0.1, col = col)
title("filledellipse")
#
emptyplot(c(-1, 1), c(-1, 1))
filledellipse(col = col, dr = 0.1)
title("filledellipse")
#
color <-gray(seq(1, 0.3, length.out = 30))
emptyplot(xlim = c(-2, 2), ylim = c(-2, 2), col = color[length(color)])
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = -45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 0, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 90, dr = 0.1)
title("filledellipse")
#
emptyplot(main = "getellipse")
col <-femmecol(90)
for (i in seq(0, 180, by = 2))
lines(getellipse(0.5, 0.25, mid = c(0.5, 0.5), angle = i, dr = 0.1),
type = "l", col = col[(i/2)+1], lwd = 2)
###################################################
### code chunk number 8: s4
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#
# simple cylinders
emptyplot(c(-1.2, 1.2), c(-1, 1), main = "filledcylinder")
col <- c(rev(greycol(n = 20)), greycol(n = 20))
col2 <- shadepalette("red", "blue", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0., ry = 0.2, len = 0.25, angle = 0,
col = col, mid = c(-1, 0), dr = 0.1)
filledcylinder(rx = 0.0, ry = 0.2, angle = 90, col = col,
mid = c(-0.5, 0), dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = c(col2, rev(col2)),
mid = c(0.45, 0), topcol = col2[10], dr = 0.1)
filledcylinder(rx = 0.05, ry = 0.2, angle = 90, col = c(col3, rev(col3)),
mid = c(0.9, 0), topcol = col3[10], dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = "white",
lcol = "black", lcolint = "grey", dr = 0.1)
#
# more complex cylinders
emptyplot(c(-1, 1), c(-1, 1), main = "filledcylinder")
col <- shadepalette("blue", "black", n = 20)
col2 <- shadepalette("red", "black", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0.025, ry = 0.2, angle = 90,
col = c(col2, rev(col2)), dr = 0.1, mid = c(-0.8, 0),
topcol = col2[10], delt = -1., lcol = "black")
filledcylinder(rx = 0.1, ry = 0.2, angle = 00,
col = c(col, rev(col)), dr = 0.1, mid = c(0.0, 0.0),
topcol = col, delt = -1.2, lcol = "black")
filledcylinder(rx = 0.075, ry = 0.2, angle = 90,
col = c(col3, rev(col3)), dr = 0.1, mid = c(0.8, 0),
topcol = col3[10], delt = 0.0, lcol = "black")
#
# rectangles
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1), main = "filledrectangle")
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0, 0), angle = 0)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, 0.5), angle = 90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, -0.5), angle = -90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, -0.5), angle = 180)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, 0.5), angle = 270)
#
# multigonal
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1))
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "blue", n = 20),
nr = 3, mid = c(0, 0), angle = 0)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "darkgreen", n = 20),
nr = 4, mid = c(0.5, 0.5), angle = 90)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "orange", n = 20),
nr = 5, mid = c(-0.5, -0.5), angle = -90)
filledmultigonal(rx = 0.25, ry = 0.25, col = "black",
nr = 6, mid = c(0.5, -0.5), angle = 180)
filledmultigonal(rx = 0.25, ry = 0.25, col = "white", lcol = "black",
nr = 7, mid = c(-0.5, 0.5), angle = 270)
title("filledmultigonal")
###################################################
### code chunk number 9: s4
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#
# simple cylinders
emptyplot(c(-1.2, 1.2), c(-1, 1), main = "filledcylinder")
col <- c(rev(greycol(n = 20)), greycol(n = 20))
col2 <- shadepalette("red", "blue", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0., ry = 0.2, len = 0.25, angle = 0,
col = col, mid = c(-1, 0), dr = 0.1)
filledcylinder(rx = 0.0, ry = 0.2, angle = 90, col = col,
mid = c(-0.5, 0), dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = c(col2, rev(col2)),
mid = c(0.45, 0), topcol = col2[10], dr = 0.1)
filledcylinder(rx = 0.05, ry = 0.2, angle = 90, col = c(col3, rev(col3)),
mid = c(0.9, 0), topcol = col3[10], dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = "white",
lcol = "black", lcolint = "grey", dr = 0.1)
#
# more complex cylinders
emptyplot(c(-1, 1), c(-1, 1), main = "filledcylinder")
col <- shadepalette("blue", "black", n = 20)
col2 <- shadepalette("red", "black", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0.025, ry = 0.2, angle = 90,
col = c(col2, rev(col2)), dr = 0.1, mid = c(-0.8, 0),
topcol = col2[10], delt = -1., lcol = "black")
filledcylinder(rx = 0.1, ry = 0.2, angle = 00,
col = c(col, rev(col)), dr = 0.1, mid = c(0.0, 0.0),
topcol = col, delt = -1.2, lcol = "black")
filledcylinder(rx = 0.075, ry = 0.2, angle = 90,
col = c(col3, rev(col3)), dr = 0.1, mid = c(0.8, 0),
topcol = col3[10], delt = 0.0, lcol = "black")
#
# rectangles
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1), main = "filledrectangle")
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0, 0), angle = 0)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, 0.5), angle = 90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, -0.5), angle = -90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, -0.5), angle = 180)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, 0.5), angle = 270)
#
# multigonal
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1))
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "blue", n = 20),
nr = 3, mid = c(0, 0), angle = 0)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "darkgreen", n = 20),
nr = 4, mid = c(0.5, 0.5), angle = 90)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "orange", n = 20),
nr = 5, mid = c(-0.5, -0.5), angle = -90)
filledmultigonal(rx = 0.25, ry = 0.25, col = "black",
nr = 6, mid = c(0.5, -0.5), angle = 180)
filledmultigonal(rx = 0.25, ry = 0.25, col = "white", lcol = "black",
nr = 7, mid = c(-0.5, 0.5), angle = 270)
title("filledmultigonal")
###################################################
### code chunk number 10: s5
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#an egg
color <- greycol(30)
emptyplot(c(-3.2, 3.2), col = color[length(color)],
main = "filledshape")
b <- 4
a <- 9
x <- seq(-sqrt(a), sqrt(a), by = 0.1)
g <- b-b/a*x^2-0.2*b*x+0.2*b/a*x^3
g[g<0] <- 0
x1 <- c(x, rev(x))
g1 <- c(sqrt(g), rev(-sqrt(g)))
xouter <- cbind(x1, g1)
xouter <- rbind(xouter, xouter[1, ])
filledshape(xouter, xyinner = c(-1, 0), col = color)
#
# a mill
color <- shadepalette(grey(0.3), "yellow", n = 20)
emptyplot(c(-3.3, 3.3), col = color[length(color)],
main = "filledshape")
x <- seq(0, 0.8*pi, pi/20)
y <- sin(x)
xouter <- cbind(x, y)
for (i in seq(0, 360, 60))
xouter <- rbind(xouter,
rotatexy(cbind(x, y), mid = c(0, 0), angle = i))
filledshape(xouter, c(0, 0), col = color)
#
# abstract art
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)), col = "darkblue")
#
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)),
col = shadepalette(20, "darkred", "darkblue"))
###################################################
### code chunk number 11: s5
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#an egg
color <- greycol(30)
emptyplot(c(-3.2, 3.2), col = color[length(color)],
main = "filledshape")
b <- 4
a <- 9
x <- seq(-sqrt(a), sqrt(a), by = 0.1)
g <- b-b/a*x^2-0.2*b*x+0.2*b/a*x^3
g[g<0] <- 0
x1 <- c(x, rev(x))
g1 <- c(sqrt(g), rev(-sqrt(g)))
xouter <- cbind(x1, g1)
xouter <- rbind(xouter, xouter[1, ])
filledshape(xouter, xyinner = c(-1, 0), col = color)
#
# a mill
color <- shadepalette(grey(0.3), "yellow", n = 20)
emptyplot(c(-3.3, 3.3), col = color[length(color)],
main = "filledshape")
x <- seq(0, 0.8*pi, pi/20)
y <- sin(x)
xouter <- cbind(x, y)
for (i in seq(0, 360, 60))
xouter <- rbind(xouter,
rotatexy(cbind(x, y), mid = c(0, 0), angle = i))
filledshape(xouter, c(0, 0), col = color)
#
# abstract art
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)), col = "darkblue")
#
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)),
col = shadepalette(20, "darkred", "darkblue"))
###################################################
### code chunk number 12: s6
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
xlim <- c(-5 , 5)
ylim <- c(-10, 10)
x0<-runif(100, xlim[1], xlim[2])
y0<-runif(100, ylim[1], ylim[2])
x1<-x0+runif(100, -2, 2)
y1<-y0+runif(100, -2, 2)
size <- 0.4
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrows(x0, y0, x1, y1, arr.length = size, arr.type = "triangle",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrows")
#
# arrow heads
#
ang <- runif(100, -360, 360)
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrowhead(x0, y0, ang, arr.length = size, arr.type = "curved",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrowhead")
#
# Lotka-Volterra competition model
#
r1 <- 3 # parameters
r2 <- 2
K1 <- 1.5
K2 <- 2
alf12 <- 1
alf21 <- 2
xlim <- c(0, 1.5)
ylim <- c(0, 2 )
par(mar = c(5, 4, 4, 2))
plot (0, type = "l", lwd = 3, # 1st isocline
main = "Lotka-Volterra competition",
xlab = "N1", ylab = "N2", xlim = xlim, ylim = ylim)
gx <- seq(0, 1.5, len = 30)
gy <- seq(0, 2, len = 30)
N <- as.matrix(expand.grid(x = gx, y = gy))
dN1 <- r1*N[, 1]*(1-(N[, 1]+alf12* N[, 2])/K1)
dN2 <- r2*N[, 2]*(1-(N[, 2]+alf21* N[, 1])/K2)
dt <- 0.01
Arrows(N[, 1], N[, 2], N[, 1]+dt*dN1, N[, 2]+dt*dN2, arr.len = 0.08,
lcol = "darkblue", arr.type = "triangle")
points(x = c(0, 0, 1.5, 0.5), y = c(0, 2, 0, 1), pch = 22, cex = 2,
bg = c("white", "black", "black", "grey"))
###################################################
### code chunk number 13: s6
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
xlim <- c(-5 , 5)
ylim <- c(-10, 10)
x0<-runif(100, xlim[1], xlim[2])
y0<-runif(100, ylim[1], ylim[2])
x1<-x0+runif(100, -2, 2)
y1<-y0+runif(100, -2, 2)
size <- 0.4
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrows(x0, y0, x1, y1, arr.length = size, arr.type = "triangle",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrows")
#
# arrow heads
#
ang <- runif(100, -360, 360)
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrowhead(x0, y0, ang, arr.length = size, arr.type = "curved",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrowhead")
#
# Lotka-Volterra competition model
#
r1 <- 3 # parameters
r2 <- 2
K1 <- 1.5
K2 <- 2
alf12 <- 1
alf21 <- 2
xlim <- c(0, 1.5)
ylim <- c(0, 2 )
par(mar = c(5, 4, 4, 2))
plot (0, type = "l", lwd = 3, # 1st isocline
main = "Lotka-Volterra competition",
xlab = "N1", ylab = "N2", xlim = xlim, ylim = ylim)
gx <- seq(0, 1.5, len = 30)
gy <- seq(0, 2, len = 30)
N <- as.matrix(expand.grid(x = gx, y = gy))
dN1 <- r1*N[, 1]*(1-(N[, 1]+alf12* N[, 2])/K1)
dN2 <- r2*N[, 2]*(1-(N[, 2]+alf21* N[, 1])/K2)
dt <- 0.01
Arrows(N[, 1], N[, 2], N[, 1]+dt*dN1, N[, 2]+dt*dN2, arr.len = 0.08,
lcol = "darkblue", arr.type = "triangle")
points(x = c(0, 0, 1.5, 0.5), y = c(0, 2, 0, 1), pch = 22, cex = 2,
bg = c("white", "black", "black", "grey"))
###################################################
### code chunk number 14: textflag
###################################################
emptyplot()
textflag(mid = c(0.5, 0.5), radx = 0.5, rady = 0.2,
lcol = "white", lab = "hello", cex = 5, font = 2:3)
###################################################
### code chunk number 15: textflag
###################################################
emptyplot()
textflag(mid = c(0.5, 0.5), radx = 0.5, rady = 0.2,
lcol = "white", lab = "hello", cex = 5, font = 2:3)
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### R code from vignette source 'shape.Rnw'
###################################################
### code chunk number 1: preliminaries
###################################################
library("shape")
options(prompt = "> ")
options(width=90)
###################################################
### code chunk number 2: s1
###################################################
par(mfrow = c(2, 2))
image(matrix(nrow = 1, ncol = 50, data = 1:50),
main = "intpalette",
col = intpalette(c("red", "blue", "yellow", "green", "black"),
numcol = 50))
#
shadepalette(n = 10, "white", "black")
#
image(matrix(nrow = 1, ncol = 50, data = 1:50),
col = shadepalette(50, "red", "blue"),
main = "shadepalette")
#
par(mar = c(0, 0, 0, 0))
persp(volcano, theta = 135, phi = 30, col = drapecol(volcano),
main = "drapecol", border = NA)
###################################################
### code chunk number 3: s1
###################################################
par(mfrow = c(2, 2))
image(matrix(nrow = 1, ncol = 50, data = 1:50),
main = "intpalette",
col = intpalette(c("red", "blue", "yellow", "green", "black"),
numcol = 50))
#
shadepalette(n = 10, "white", "black")
#
image(matrix(nrow = 1, ncol = 50, data = 1:50),
col = shadepalette(50, "red", "blue"),
main = "shadepalette")
#
par(mar = c(0, 0, 0, 0))
persp(volcano, theta = 135, phi = 30, col = drapecol(volcano),
main = "drapecol", border = NA)
###################################################
### code chunk number 4: s2
###################################################
par(mfrow = c(2, 2), mar = c(3, 3, 3, 3))
#
# rotating points on a line
#
xy <- matrix(ncol = 2, data = c(1:5, rep(1, 5)))
plot(xy, xlim = c(-6, 6), ylim = c(-6, 6), type = "b",
pch = 16, main = "rotatexy", col = 1)
for (i in 1:5)
points(rotatexy(xy, mid = c(0, 0), angle = 60*i),
col = i+1, type = "b", pch = 16)
points(0, 0, cex = 2, pch = 22, bg = "black")
legend("topright", legend = 60*(0:5), col = 1:6, pch = 16,
title = "angle")
legend("topleft", legend = "midpoint", pt.bg = "black",
pt.cex = 2, pch = 22, box.lty = 0)
#
# rotating lines..
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x)
cols <- intpalette(c("blue", "green", "yellow", "red"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-3, 3), main = "rotatexy",
col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i), col = cols[i], lwd = 2)
#
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x*2)
cols <- intpalette(c("red", "yellow", "black"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-4, 5), main = "rotatexy,
asp = TRUE", col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i, asp = TRUE),
col = cols[i], lwd = 2)
#
# rotating points
#
cols <- femmecol(500)
plot(x, y, xlim = c(-1, 1), ylim = c(-1, 1), main = "rotatexy",
col = cols[1], type = "n")
for (i in 2:500) {
xy <- rotatexy(c(0, 1), angle = 0.72*i, mid = c(0, 0))
points(xy[1], xy[2], col = cols[i], pch = ".", cex = 2)
}
###################################################
### code chunk number 5: s2
###################################################
par(mfrow = c(2, 2), mar = c(3, 3, 3, 3))
#
# rotating points on a line
#
xy <- matrix(ncol = 2, data = c(1:5, rep(1, 5)))
plot(xy, xlim = c(-6, 6), ylim = c(-6, 6), type = "b",
pch = 16, main = "rotatexy", col = 1)
for (i in 1:5)
points(rotatexy(xy, mid = c(0, 0), angle = 60*i),
col = i+1, type = "b", pch = 16)
points(0, 0, cex = 2, pch = 22, bg = "black")
legend("topright", legend = 60*(0:5), col = 1:6, pch = 16,
title = "angle")
legend("topleft", legend = "midpoint", pt.bg = "black",
pt.cex = 2, pch = 22, box.lty = 0)
#
# rotating lines..
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x)
cols <- intpalette(c("blue", "green", "yellow", "red"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-3, 3), main = "rotatexy",
col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i), col = cols[i], lwd = 2)
#
#
x <- seq(0, 2*pi, pi/20)
y <- sin(x*2)
cols <- intpalette(c("red", "yellow", "black"), n = 125)
cols <- c(cols, rev(cols))
plot(x, y, type = "l", ylim = c(-4, 5), main = "rotatexy,
asp = TRUE", col = cols[1], lwd = 2, xlim = c(-1, 7))
for (i in 2:250)
lines(rotatexy(cbind(x, y), angle = 0.72*i, asp = TRUE),
col = cols[i], lwd = 2)
#
# rotating points
#
cols <- femmecol(500)
plot(x, y, xlim = c(-1, 1), ylim = c(-1, 1), main = "rotatexy",
col = cols[1], type = "n")
for (i in 2:500) {
xy <- rotatexy(c(0, 1), angle = 0.72*i, mid = c(0, 0))
points(xy[1], xy[2], col = cols[i], pch = ".", cex = 2)
}
###################################################
### code chunk number 6: s3
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
emptyplot(c(-1, 1))
col <- c(rev(greycol(n = 30)), greycol(30))
filledellipse(rx1 = 1, rx2 = 0.5, dr = 0.1, col = col)
title("filledellipse")
#
emptyplot(c(-1, 1), c(-1, 1))
filledellipse(col = col, dr = 0.1)
title("filledellipse")
#
color <-gray(seq(1, 0.3, length.out = 30))
emptyplot(xlim = c(-2, 2), ylim = c(-2, 2), col = color[length(color)])
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = -45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 0, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 90, dr = 0.1)
title("filledellipse")
#
emptyplot(main = "getellipse")
col <-femmecol(90)
for (i in seq(0, 180, by = 2))
lines(getellipse(0.5, 0.25, mid = c(0.5, 0.5), angle = i, dr = 0.1),
type = "l", col = col[(i/2)+1], lwd = 2)
###################################################
### code chunk number 7: s3
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
emptyplot(c(-1, 1))
col <- c(rev(greycol(n = 30)), greycol(30))
filledellipse(rx1 = 1, rx2 = 0.5, dr = 0.1, col = col)
title("filledellipse")
#
emptyplot(c(-1, 1), c(-1, 1))
filledellipse(col = col, dr = 0.1)
title("filledellipse")
#
color <-gray(seq(1, 0.3, length.out = 30))
emptyplot(xlim = c(-2, 2), ylim = c(-2, 2), col = color[length(color)])
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = -45, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 0, dr = 0.1)
filledellipse(rx1 = 2, ry1 = 0.4, col = color, angle = 90, dr = 0.1)
title("filledellipse")
#
emptyplot(main = "getellipse")
col <-femmecol(90)
for (i in seq(0, 180, by = 2))
lines(getellipse(0.5, 0.25, mid = c(0.5, 0.5), angle = i, dr = 0.1),
type = "l", col = col[(i/2)+1], lwd = 2)
###################################################
### code chunk number 8: s4
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#
# simple cylinders
emptyplot(c(-1.2, 1.2), c(-1, 1), main = "filledcylinder")
col <- c(rev(greycol(n = 20)), greycol(n = 20))
col2 <- shadepalette("red", "blue", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0., ry = 0.2, len = 0.25, angle = 0,
col = col, mid = c(-1, 0), dr = 0.1)
filledcylinder(rx = 0.0, ry = 0.2, angle = 90, col = col,
mid = c(-0.5, 0), dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = c(col2, rev(col2)),
mid = c(0.45, 0), topcol = col2[10], dr = 0.1)
filledcylinder(rx = 0.05, ry = 0.2, angle = 90, col = c(col3, rev(col3)),
mid = c(0.9, 0), topcol = col3[10], dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = "white",
lcol = "black", lcolint = "grey", dr = 0.1)
#
# more complex cylinders
emptyplot(c(-1, 1), c(-1, 1), main = "filledcylinder")
col <- shadepalette("blue", "black", n = 20)
col2 <- shadepalette("red", "black", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0.025, ry = 0.2, angle = 90,
col = c(col2, rev(col2)), dr = 0.1, mid = c(-0.8, 0),
topcol = col2[10], delt = -1., lcol = "black")
filledcylinder(rx = 0.1, ry = 0.2, angle = 00,
col = c(col, rev(col)), dr = 0.1, mid = c(0.0, 0.0),
topcol = col, delt = -1.2, lcol = "black")
filledcylinder(rx = 0.075, ry = 0.2, angle = 90,
col = c(col3, rev(col3)), dr = 0.1, mid = c(0.8, 0),
topcol = col3[10], delt = 0.0, lcol = "black")
#
# rectangles
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1), main = "filledrectangle")
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0, 0), angle = 0)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, 0.5), angle = 90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, -0.5), angle = -90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, -0.5), angle = 180)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, 0.5), angle = 270)
#
# multigonal
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1))
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "blue", n = 20),
nr = 3, mid = c(0, 0), angle = 0)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "darkgreen", n = 20),
nr = 4, mid = c(0.5, 0.5), angle = 90)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "orange", n = 20),
nr = 5, mid = c(-0.5, -0.5), angle = -90)
filledmultigonal(rx = 0.25, ry = 0.25, col = "black",
nr = 6, mid = c(0.5, -0.5), angle = 180)
filledmultigonal(rx = 0.25, ry = 0.25, col = "white", lcol = "black",
nr = 7, mid = c(-0.5, 0.5), angle = 270)
title("filledmultigonal")
###################################################
### code chunk number 9: s4
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#
# simple cylinders
emptyplot(c(-1.2, 1.2), c(-1, 1), main = "filledcylinder")
col <- c(rev(greycol(n = 20)), greycol(n = 20))
col2 <- shadepalette("red", "blue", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0., ry = 0.2, len = 0.25, angle = 0,
col = col, mid = c(-1, 0), dr = 0.1)
filledcylinder(rx = 0.0, ry = 0.2, angle = 90, col = col,
mid = c(-0.5, 0), dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = c(col2, rev(col2)),
mid = c(0.45, 0), topcol = col2[10], dr = 0.1)
filledcylinder(rx = 0.05, ry = 0.2, angle = 90, col = c(col3, rev(col3)),
mid = c(0.9, 0), topcol = col3[10], dr = 0.1)
filledcylinder(rx = 0.1, ry = 0.2, angle = 90, col = "white",
lcol = "black", lcolint = "grey", dr = 0.1)
#
# more complex cylinders
emptyplot(c(-1, 1), c(-1, 1), main = "filledcylinder")
col <- shadepalette("blue", "black", n = 20)
col2 <- shadepalette("red", "black", n = 20)
col3 <- shadepalette("yellow", "black", n = 20)
filledcylinder(rx = 0.025, ry = 0.2, angle = 90,
col = c(col2, rev(col2)), dr = 0.1, mid = c(-0.8, 0),
topcol = col2[10], delt = -1., lcol = "black")
filledcylinder(rx = 0.1, ry = 0.2, angle = 00,
col = c(col, rev(col)), dr = 0.1, mid = c(0.0, 0.0),
topcol = col, delt = -1.2, lcol = "black")
filledcylinder(rx = 0.075, ry = 0.2, angle = 90,
col = c(col3, rev(col3)), dr = 0.1, mid = c(0.8, 0),
topcol = col3[10], delt = 0.0, lcol = "black")
#
# rectangles
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1), main = "filledrectangle")
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0, 0), angle = 0)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, 0.5), angle = 90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, -0.5), angle = -90)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(0.5, -0.5), angle = 180)
filledrectangle(wx = 0.5, wy = 0.5, col = color,
mid = c(-0.5, 0.5), angle = 270)
#
# multigonal
color <- shadepalette(grey(0.3), "blue", n = 20)
emptyplot(c(-1, 1))
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "blue", n = 20),
nr = 3, mid = c(0, 0), angle = 0)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "darkgreen", n = 20),
nr = 4, mid = c(0.5, 0.5), angle = 90)
filledmultigonal(rx = 0.25, ry = 0.25,
col = shadepalette(grey(0.3), "orange", n = 20),
nr = 5, mid = c(-0.5, -0.5), angle = -90)
filledmultigonal(rx = 0.25, ry = 0.25, col = "black",
nr = 6, mid = c(0.5, -0.5), angle = 180)
filledmultigonal(rx = 0.25, ry = 0.25, col = "white", lcol = "black",
nr = 7, mid = c(-0.5, 0.5), angle = 270)
title("filledmultigonal")
###################################################
### code chunk number 10: s5
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#an egg
color <- greycol(30)
emptyplot(c(-3.2, 3.2), col = color[length(color)],
main = "filledshape")
b <- 4
a <- 9
x <- seq(-sqrt(a), sqrt(a), by = 0.1)
g <- b-b/a*x^2-0.2*b*x+0.2*b/a*x^3
g[g<0] <- 0
x1 <- c(x, rev(x))
g1 <- c(sqrt(g), rev(-sqrt(g)))
xouter <- cbind(x1, g1)
xouter <- rbind(xouter, xouter[1, ])
filledshape(xouter, xyinner = c(-1, 0), col = color)
#
# a mill
color <- shadepalette(grey(0.3), "yellow", n = 20)
emptyplot(c(-3.3, 3.3), col = color[length(color)],
main = "filledshape")
x <- seq(0, 0.8*pi, pi/20)
y <- sin(x)
xouter <- cbind(x, y)
for (i in seq(0, 360, 60))
xouter <- rbind(xouter,
rotatexy(cbind(x, y), mid = c(0, 0), angle = i))
filledshape(xouter, c(0, 0), col = color)
#
# abstract art
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)), col = "darkblue")
#
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)),
col = shadepalette(20, "darkred", "darkblue"))
###################################################
### code chunk number 11: s5
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
#an egg
color <- greycol(30)
emptyplot(c(-3.2, 3.2), col = color[length(color)],
main = "filledshape")
b <- 4
a <- 9
x <- seq(-sqrt(a), sqrt(a), by = 0.1)
g <- b-b/a*x^2-0.2*b*x+0.2*b/a*x^3
g[g<0] <- 0
x1 <- c(x, rev(x))
g1 <- c(sqrt(g), rev(-sqrt(g)))
xouter <- cbind(x1, g1)
xouter <- rbind(xouter, xouter[1, ])
filledshape(xouter, xyinner = c(-1, 0), col = color)
#
# a mill
color <- shadepalette(grey(0.3), "yellow", n = 20)
emptyplot(c(-3.3, 3.3), col = color[length(color)],
main = "filledshape")
x <- seq(0, 0.8*pi, pi/20)
y <- sin(x)
xouter <- cbind(x, y)
for (i in seq(0, 360, 60))
xouter <- rbind(xouter,
rotatexy(cbind(x, y), mid = c(0, 0), angle = i))
filledshape(xouter, c(0, 0), col = color)
#
# abstract art
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)), col = "darkblue")
#
emptyplot(col = "darkgrey", main = "filledshape")
filledshape(matrix(nc = 2, runif(80)),
col = shadepalette(20, "darkred", "darkblue"))
###################################################
### code chunk number 12: s6
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
xlim <- c(-5 , 5)
ylim <- c(-10, 10)
x0<-runif(100, xlim[1], xlim[2])
y0<-runif(100, ylim[1], ylim[2])
x1<-x0+runif(100, -2, 2)
y1<-y0+runif(100, -2, 2)
size <- 0.4
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrows(x0, y0, x1, y1, arr.length = size, arr.type = "triangle",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrows")
#
# arrow heads
#
ang <- runif(100, -360, 360)
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrowhead(x0, y0, ang, arr.length = size, arr.type = "curved",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrowhead")
#
# Lotka-Volterra competition model
#
r1 <- 3 # parameters
r2 <- 2
K1 <- 1.5
K2 <- 2
alf12 <- 1
alf21 <- 2
xlim <- c(0, 1.5)
ylim <- c(0, 2 )
par(mar = c(5, 4, 4, 2))
plot (0, type = "l", lwd = 3, # 1st isocline
main = "Lotka-Volterra competition",
xlab = "N1", ylab = "N2", xlim = xlim, ylim = ylim)
gx <- seq(0, 1.5, len = 30)
gy <- seq(0, 2, len = 30)
N <- as.matrix(expand.grid(x = gx, y = gy))
dN1 <- r1*N[, 1]*(1-(N[, 1]+alf12* N[, 2])/K1)
dN2 <- r2*N[, 2]*(1-(N[, 2]+alf21* N[, 1])/K2)
dt <- 0.01
Arrows(N[, 1], N[, 2], N[, 1]+dt*dN1, N[, 2]+dt*dN2, arr.len = 0.08,
lcol = "darkblue", arr.type = "triangle")
points(x = c(0, 0, 1.5, 0.5), y = c(0, 2, 0, 1), pch = 22, cex = 2,
bg = c("white", "black", "black", "grey"))
###################################################
### code chunk number 13: s6
###################################################
par(mfrow = c(2, 2), mar = c(2, 2, 2, 2))
xlim <- c(-5 , 5)
ylim <- c(-10, 10)
x0<-runif(100, xlim[1], xlim[2])
y0<-runif(100, ylim[1], ylim[2])
x1<-x0+runif(100, -2, 2)
y1<-y0+runif(100, -2, 2)
size <- 0.4
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrows(x0, y0, x1, y1, arr.length = size, arr.type = "triangle",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrows")
#
# arrow heads
#
ang <- runif(100, -360, 360)
plot(0, type = "n", xlim = xlim, ylim = ylim)
Arrowhead(x0, y0, ang, arr.length = size, arr.type = "curved",
arr.col = rainbow(runif(100, 1, 20)))
title("Arrowhead")
#
# Lotka-Volterra competition model
#
r1 <- 3 # parameters
r2 <- 2
K1 <- 1.5
K2 <- 2
alf12 <- 1
alf21 <- 2
xlim <- c(0, 1.5)
ylim <- c(0, 2 )
par(mar = c(5, 4, 4, 2))
plot (0, type = "l", lwd = 3, # 1st isocline
main = "Lotka-Volterra competition",
xlab = "N1", ylab = "N2", xlim = xlim, ylim = ylim)
gx <- seq(0, 1.5, len = 30)
gy <- seq(0, 2, len = 30)
N <- as.matrix(expand.grid(x = gx, y = gy))
dN1 <- r1*N[, 1]*(1-(N[, 1]+alf12* N[, 2])/K1)
dN2 <- r2*N[, 2]*(1-(N[, 2]+alf21* N[, 1])/K2)
dt <- 0.01
Arrows(N[, 1], N[, 2], N[, 1]+dt*dN1, N[, 2]+dt*dN2, arr.len = 0.08,
lcol = "darkblue", arr.type = "triangle")
points(x = c(0, 0, 1.5, 0.5), y = c(0, 2, 0, 1), pch = 22, cex = 2,
bg = c("white", "black", "black", "grey"))
###################################################
### code chunk number 14: textflag
###################################################
emptyplot()
textflag(mid = c(0.5, 0.5), radx = 0.5, rady = 0.2,
lcol = "white", lab = "hello", cex = 5, font = 2:3)
###################################################
### code chunk number 15: textflag
###################################################
emptyplot()
textflag(mid = c(0.5, 0.5), radx = 0.5, rady = 0.2,
lcol = "white", lab = "hello", cex = 5, font = 2:3)
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