Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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:

enter image description here

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.

Here is the start with drawing circles:

## 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: enter image description here

And here's the code.

share|improve this question
    
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

4 Answers 4

up vote 8 down vote accepted

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
grad.circ <- function(centrex,centrey,radius,col,resolution) {
  colfunc <- colorRampPalette(col)
  shades <- colfunc(resolution)

  for (i in seq_along(shades) ) {
   clip(
      centrex - radius,
      centrex + radius,
      (centrey + radius) - ((i-1) * (radius*2)/length(shades)),
      (centrey + radius) - (i     * (radius*2)/length(shades))
       )
   symbols(
     centrex,
     centrey,
     circles=radius,
     bg=shades[i],
     fg=NA,
     add=TRUE,
     inches=FALSE
          )
  }
}

# call the function
grad.circ(0.5,0.5,0.5,c("black", "white"),300)

Result:

enter image description here

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) {
        grad.circ(0.5, 0.5, 0.5, cols, 300)
    }
}

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()))
share|improve this answer
    
+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
1  
@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.

share|improve this answer
    
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.

share|improve this answer
    
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, 
                 width=0.45, quadsegs=100)
    b2 <- gBuffer(SpatialPoints(cbind(rep(5:7, 3), rep(1:3, each=3))), TRUE, 
                  width=0.45, quadsegs=100)
    
    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)), 
         col='gray80', border='gray80', add=TRUE)
    
  5. For bonus circle smoothness, plot the circles once more, with colour equal to the background colour.

    plot(gUnion(b, b2), border='gray80', lwd=2, add=TRUE)
    

gradient bubbles

share|improve this answer
    
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
    
Nice, worked very well and the breakdown was nice too. –  Tyler Rinker Feb 16 at 23:36

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.