I am attempting to reproduce a Stephen Few graphic with gradient circles that demonstrates the hard wired assumption that light appears from above. Here are the circles:

How can I recreate this? Drawing the circles isn't too bad but adding gradient is where I get thrown. I am thinking grid may create something more crisp but this may be a misconception I have.

``````## John Fox circle function
source("http://dl.dropboxusercontent.com/u/61803503/wordpress/circle_fun.txt")

par(mar=rep(1, 4), bg = "grey80")
plot.new()

for (i in seq(0, 1, by = .2)) {
for (j in seq(.6, 1, by = .1)) {
circle(i, j, .5, "cm", , 1)
}
}
``````

Related question: How to use R to build bubble charts with gradient fills

EDIT:

Thought I'd share the results:

And here's the code.

-
how smooth do you need the gradient to be? –  Ricardo Saporta Jun 27 '13 at 3:05
Enough to retain the illusion but you can see the lines in the gradient above. –  Tyler Rinker Jun 27 '13 at 3:06
Perhaps you can create several rows of black-to-white gradients, then plot over them? This question on gradients: stackoverflow.com/questions/11070101/… –  Ricardo Saporta Jun 27 '13 at 3:08

With some repeated use of `clip`, you can get there.

``````# set up a blank plot
par(mar=rep(0, 4))
par(bg="#cccccc")
plot(NA,xlim=0:1,ylim=0:1)

# define a function
colfunc <- colorRampPalette(col)

for (i in seq_along(shades) ) {
clip(
)
symbols(
centrex,
centrey,
fg=NA,
inches=FALSE
)
}
}

# call the function
``````

Result:

EDIT (by Tyler Rinker):

I wanted to add the rest of the code I used to replicate the image:

``````FUN <- function(plot = TRUE, cols = c("black", "white")) {
plot(NA, xlim=0:1, ylim=0:1, axes=FALSE)
if (plot) {
}
}

FUN2 <- function(){
lapply(1:3, function(i) FUN(,c("white", "black")))
FUN(F)
lapply(1:3, function(i) FUN())
}

X11(10, 4.5)
par(mfrow=c(3, 7))
par(mar=rep(0, 4))
par(bg="gray70")
invisible(lapply(1:3, function(i) FUN2()))
``````
-
+1 very nice. Thank you greatly. –  Tyler Rinker Jun 27 '13 at 3:40
I've never seen clip used. I'm trying to extend this. How can I make the circles smaller? In other words what is controlling circle radius? –  Tyler Rinker Jun 27 '13 at 3:51
@TylerRinker - I have generalised the code now so hopefully it makes sense. –  thelatemail Jun 27 '13 at 3:59

Here is a version using rasters and `rasterImage`:

``````image <- as.raster( matrix( seq(0,1,length.out=1001), nrow=1001, ncol=1001) )
tmp <- ( row(image) - 501 ) ^2 + ( col(image) - 501 )^2
image[tmp > 500^2] <- NA

image2 <- as.raster( matrix( seq(1,0, length.out=1001), nrow=1001, ncol=1001) )
image2[ tmp > 500^2 ] <- NA

image3 <- row(image) + col(image)
image3 <- image3/max(image3)
image3[tmp>500^2] <- NA
image4 <- 1-image3
image3 <- as.raster(image3)
image4 <- as.raster(image4)

plot( 0:1, 0:1, type='n', asp=1,ann=FALSE,axes=FALSE)
rect(0,0,1,1, col='grey')
rasterImage(image, 0.2, 0.2, 0.3, 0.3)
rasterImage(image2, 0.6, 0.6, 0.7, 0.7)
rasterImage(image3, 0.6, 0.3, 0.7, 0.4)
rasterImage(image4, 0.3, 0.7, 0.4, 0.8)
``````

Other directions of shading can be made by changing the math a little.

-
This also works very nicely +1 –  Tyler Rinker Jun 27 '13 at 13:58

You can do this using the (not on CRAN) package `zernike` . It's designed to produce various images related to Zernike polynomials, heavily used in optics & astronomy systems. Your desired images are pretty much the second Zernike term.

The author is Author: M.L. Peck (mpeck1@ix.netcom.com) ; I forget exactly where the R-package resides on hte web.

-
Here's the link: wildlife-pix.com/rpackages but I couldn't apply it to this problem. And it was built pre R 3.0.0. –  Tyler Rinker Jun 27 '13 at 12:58
@TylerRinker Thanks for finding it. I never build it; just use the R-functions included. –  Carl Witthoft Jun 27 '13 at 13:36
Oh I gotcha. :) –  Tyler Rinker Jun 27 '13 at 13:59

And here's an approach using `sp` and `rgeos` (similar application here and here).

``````library(sp)
library(rgeos)
library(raster)
``````
1. Create two sets of 9 circles by buffering points, then plot their union to set up the plotting area.

``````b <- gBuffer(SpatialPoints(cbind(rep(1:3, 3), rep(1:3, each=3))), TRUE,
b2 <- gBuffer(SpatialPoints(cbind(rep(5:7, 3), rep(1:3, each=3))), TRUE,

plot(gUnion(b, b2), border=NA)
``````
2. Step through the polygons and extract their bounding boxes.

``````bb <- sapply(b@polygons, bbox)
bb2 <- sapply(b2@polygons, bbox)
``````
3. Plot stacked segments to simulate a gradient.

``````segments(rep(bb[1,], each=1000),
mapply(seq, bb[2,], bb[4,], len=1000),
rep(bb[3,], each=1000), col=gray.colors(1000, 0))

segments(rep(bb2[1,], each=1000),
mapply(seq, bb2[2,], bb2[4,], len=1000),
rep(bb2[3,], each=1000), col=rev(gray.colors(1000, 0)))
``````
4. Difference the union of the `SpatialPolygon` objects and plot the differenced polygon to mask out the non-circles areas.

``````plot(gDifference(as(extent(par('usr')), 'SpatialPolygons'), gUnion(b, b2)),
``````plot(gUnion(b, b2), border='gray80', lwd=2, add=TRUE)
Looks very promising for smoothness. Where is the `extent` function from in step 4? –  Tyler Rinker Feb 16 at 14:48
@Tyler - `raster ` ... Sorry bout that. –  jbaums Feb 16 at 21:32