I am plotting a categorical dataset and want to use distinctive colors to represent different categories. Given a number n, how can I get n number of MOST distinctive colors in R? Thanks.


11 Answers 11


I joined all qualitative palettes from RColorBrewer package. Qualitative palettes are supposed to provide X most distinctive colours each. Of course, mixing them joins into one palette also similar colours, but that's the best I can get (74 colors).

n <- 60
qual_col_pals = brewer.pal.info[brewer.pal.info$category == 'qual',]
col_vector = unlist(mapply(brewer.pal, qual_col_pals$maxcolors, rownames(qual_col_pals)))
pie(rep(1,n), col=sample(col_vector, n))


Other solution is: take all R colors from graphical devices and sample from them. I removed shades of grey as they are too similar. This gives 433 colors

color = grDevices::colors()[grep('gr(a|e)y', grDevices::colors(), invert = T)]

set of 20 colours

pie(rep(1,n), col=sample(color, n))

with 200 colors n = 200:

pie(rep(1,n), col=sample(color, n))

set of 200 colours

  • Is there a possibility to convert the hex codes in col to corresponding color names?
    – Prradep
    Commented Jul 13, 2017 at 13:50
  • @Prradep which col do you mean? the color from graphical devices has names. If you mean in general, not all hex code have corresponding color names (there are only 433 colors in grDevices but many more hex codes) Commented Jul 13, 2017 at 15:31
  • I am mentioning about col=sample(col_vector, n) from the RColorBrewer package in your code snippet. For example, How to find the color names for #B3E2CD, #E78AC3, #B3DE69 available from sample(col_vector,3). Alternatively, How to find all the hex codes given by brewer.pal function with their color names.
    – Prradep
    Commented Jul 13, 2017 at 15:34
  • 2
    @Prradep, as RColorBrewer palettes are not derived from grDevices colors, that have names mapped, but are just hex codes, to my knowledge, you cannot do this with RColorBrewer palettes, even qualitative ones. Commented Jul 14, 2017 at 8:16
  • 1
    @ytu then the colors are not distinguishable. If absolutely necessary, I would suggest looking for "gradient creation" in R and then use randomised sampling of colors. But mapping from colors to factors will not work, human perception can handle maybe 20 - 40 colors, the rest is not that much different. Commented Jul 3, 2019 at 12:16

Here are a few options:

  1. Have a look at the palette function:

     palette(rainbow(6))     # six color rainbow
     (palette(gray(seq(0,.9,len = 25)))) #grey scale
  2. And the colorRampPalette function:

     ##Move from blue to red in four colours
     colorRampPalette(c("blue", "red"))( 4) 
  3. Look at the RColorBrewer package (and website). If you want diverging colours, then select diverging on the site. For example,

     brewer.pal(7, "BrBG")
  4. The I want hue web site gives lots of nice palettes. Again, just select the palette that you need. For example, you can get the rgb colours from the site and make your own palette:

     palette(c(rgb(170,93,152, maxColorValue=255),
         rgb(103,143,57, maxColorValue=255),
         rgb(196,95,46, maxColorValue=255),
         rgb(79,134,165, maxColorValue=255),
         rgb(205,71,103, maxColorValue=255),
         rgb(203,77,202, maxColorValue=255),
         rgb(115,113,206, maxColorValue=255)))
  • thanks for your answer. It generates colors, but some not very distinctive with each other. maybe I should have emphasized more on that in my questions.
    – RNA
    Commented Mar 7, 2013 at 22:15
  • 1
    @RNAer I've updated my answer. You can use suggestions 3 and 4 to get diverging palettes. Commented Mar 7, 2013 at 22:19
  • 1
    I want hue is a awesome website. This is exactly what I want. Given a number, how to generate a palette of the number of colors. but can we do it in R automatically?
    – RNA
    Commented Mar 7, 2013 at 22:34
  • It is awesome. However, there's a lot of machinery behind that web site. I don't think it will be trivial to re-implement. It would be nice if i want hue had an API that allowed it to be automatically queried (maybe it does -- I didn't spend long looking)
    – Ben Bolker
    Commented Mar 7, 2013 at 22:41
  • 9
    @BenBolker - I've made a gist for an R version of i want hue, here. Efficiency could be improved (e.g. by saving colour samples as data objects), but the general idea is there. (Load with devtools::source_gist('45b49da5e260a9fc1cd7'))
    – jbaums
    Commented Nov 23, 2014 at 16:00

You can also try the randomcoloR package:

n <- 20
palette <- distinctColorPalette(n)

You can see that a set of highly distinct colors are chosen when visualizing in a pie chart (as suggested by other answers here):

pie(rep(1, n), col=palette)

enter image description here

Shown in a pie chart with 50 colors:

n <- 50
palette <- distinctColorPalette(n)
pie(rep(1, n), col=palette)

enter image description here

  • 7
    Thanks. I had to use unname(distinctColorPalette(n)) to make this work with ggplot. I guess ggplot needs an unnamed vector. col_vector <- unname(distinctColorPalette(n)) and then ... + scale_color_manual(values=col_vector) ...
    – Gaurav
    Commented Aug 22, 2017 at 4:15

Not an answer to OP's question but it's worth mentioning that there is the viridis package which has good color palettes for sequential data. They are perceptually uniform, colorblind safe and printer-friendly.

To get the palette, simply install the package and use the function viridis_pal(). There are four options "A", "B", "C" and "D" to choose

viridis_pal(option = "D")(n)  # n = number of colors seeked

enter image description here

enter image description here

enter image description here

There is also an excellent talk explaining the complexity of good colormaps on YouTube:

A Better Default Colormap for Matplotlib | SciPy 2015 | Nathaniel Smith and Stéfan van der Walt

  • 29
    This is not so suitable for distinctive colours. Commented Oct 13, 2017 at 7:43

You can use colorRampPalette from base or RColorBrewer package:

With colorRampPalette, you can specify colours as follows:

colorRampPalette(c("red", "green"))(5)
# [1] "#FF0000" "#BF3F00" "#7F7F00" "#3FBF00" "#00FF00"

You can alternatively provide hex codes as well:

colorRampPalette(c("#3794bf", "#FFFFFF", "#df8640"))(5)
# [1] "#3794BF" "#9BC9DF" "#FFFFFF" "#EFC29F" "#DF8640"
# Note that the mid color is the mid value...

With RColorBrewer you could use colors from pre-existing palettes:

brewer.pal(9, "Set1")
# [1] "#E41A1C" "#377EB8" "#4DAF4A" "#984EA3" "#FF7F00" "#FFFF33" "#A65628" "#F781BF"
# [9] "#999999"

Look at RColorBrewer package for other available palettes. Hope this helps.

  • 1
    Thanks. I like the last option brewer.pal. but it is limited up to 9 colors. I actually have more than 9 categories. The first alternatives generate a gradient colors, which is not as distinctive as I want.
    – RNA
    Commented Mar 7, 2013 at 22:19
  • 2
    you won't be able to choose many "distinct" colours. You can get a maximum of 12 I suppose. You should check out colorbrewer2.org and get the colours (there's 1 12 colour palette if I'm right).
    – Arun
    Commented Mar 7, 2013 at 22:21
  • Looking for more than 12 distinctive colouts will be difficult - I think there's discussion about that on the colorbrewer page
    – alexwhan
    Commented Mar 7, 2013 at 22:27
  • that's fine, as long as they are the "most" distinctive colors available, even they are becoming less distinctive when number goes up.
    – RNA
    Commented Mar 7, 2013 at 22:29
  • 3
    If your issue is similar colours side-by-side when assigned to adjacent categories (as the rainbow palette will do), then you could simply randomize the rainbow output with something like: rainbow(n=10)[sample(10)] Commented Sep 8, 2015 at 7:24

I would recomend to use an external source for large color palettes.


has a service to compose any size of palette according to various parameters and


discusses the generic problem from a graphics designers perspective and gives lots of examples of usable palettes.

To comprise a palette from RGB values you just have to copy the values in a vector as in e.g.:

colors37 = c("#466791","#60bf37","#953ada","#4fbe6c","#ce49d3","#a7b43d","#5a51dc","#d49f36","#552095","#507f2d","#db37aa","#84b67c","#a06fda","#df462a","#5b83db","#c76c2d","#4f49a3","#82702d","#dd6bbb","#334c22","#d83979","#55baad","#dc4555","#62aad3","#8c3025","#417d61","#862977","#bba672","#403367","#da8a6d","#a79cd4","#71482c","#c689d0","#6b2940","#d593a7","#895c8b","#bd5975")
  • You can even use a R package to get the list
    – timat
    Commented May 30 at 8:56

You can use the Polychrome package for this purpose. It just requires the number of colors and a few seedcolors. For example:

# install.packages("Polychrome")

# create your own color palette based on `seedcolors`
P36 = createPalette(36,  c("#ff0000", "#00ff00", "#0000ff"))

You can learn more about this package at https://www.jstatsoft.org/article/view/v090c01.

  • Polychrome looks interesting but doesn't appear to have been updated to be able to use R v4.
    – Ian
    Commented Mar 17, 2022 at 9:51
  • Fixed: download followed by install.packages("scatterplot3d"), install.packages("C:\\...\\Polychrome_1.3.1.tar.gz", repos = NULL, type="source")
    – Ian
    Commented Mar 17, 2022 at 13:57

I found a website offering a list of 20 distinctive colours: https://sashat.me/2017/01/11/list-of-20-simple-distinct-colors/

col_vector<-c('#e6194b', '#3cb44b', '#ffe119', '#4363d8', '#f58231', '#911eb4', '#46f0f0', '#f032e6', '#bcf60c', '#fabebe', '#008080', '#e6beff', '#9a6324', '#fffac8', '#800000', '#aaffc3', '#808000', '#ffd8b1', '#000075', '#808080', '#ffffff', '#000000')

You can have a try!

  • 4
    This doesn't really answer the question, which is about generating n distinctive colors, not a set of defined colors. Try updating your answer
    – Michal
    Commented Nov 26, 2018 at 2:37

You can generate a set of colors like this:

myCol = c("pink1", "violet", "mediumpurple1", "slateblue1", "purple", "purple3",
          "turquoise2", "skyblue", "steelblue", "blue2", "navyblue",
          "orange", "tomato", "coral2", "palevioletred", "violetred", "red2",
          "springgreen2", "yellowgreen", "palegreen4",
          "wheat2", "tan", "tan2", "tan3", "brown",
          "grey70", "grey50", "grey30")

These colors are as distinct as possible. For those similar colors, they form a gradient so that you can easily tell the differences between them.


In my understanding searching distinctive colors is related to search efficiently from an unit cube, where 3 dimensions of the cube are three vectors along red, green and blue axes. This can be simplified to search in a cylinder (HSV analogy), where you fix Saturation (S) and Value (V) and find random Hue values. It works in many cases, and see this here :


In R,

get_distinct_hues <- function(ncolor,s=0.5,v=0.95,seed=40) {
  golden_ratio_conjugate <- 0.618033988749895
  h <- runif(1)
  H <- vector("numeric",ncolor)
  for(i in seq_len(ncolor)) {
    h <- (h + golden_ratio_conjugate) %% 1
    H[i] <- h

An alternative way, is to use R package "uniformly" https://cran.r-project.org/web/packages/uniformly/index.html

and this simple function can generate distinctive colors:

get_random_distinct_colors <- function(ncolor,seed = 100) {
  rgb_mat <- runif_in_cube(n=ncolor,d=3,O=rep(0.5,3),r=0.5)

One can think of a little bit more involved function by grid-search:

get_random_grid_colors <- function(ncolor,seed = 100) {
  ngrid <- ceiling(ncolor^(1/3))
  x <- seq(0,1,length=ngrid+1)[1:ngrid]
  dx <- (x[2] - x[1])/2
  x <- x + dx
  origins <- expand.grid(x,x,x)
  nbox <- nrow(origins) 
  RGB <- vector("numeric",nbox)
  for(i in seq_len(nbox)) {
    rgb <- runif_in_cube(n=1,d=3,O=as.numeric(origins[i,]),r=dx)
    RGB[i] <- rgb(rgb[1,1],rgb[1,2],rgb[1,3])
  index <- sample(seq(1,nbox),ncolor)

check this functions by:

ncolor <- 20
barplot(rep(1,ncolor),col=get_distinct_hues(ncolor))          # approach 1
barplot(rep(1,ncolor),col=get_random_distinct_colors(ncolor)) # approach 2
barplot(rep(1,ncolor),col=get_random_grid_colors(ncolor))     # approach 3

However, note that, defining a distinct palette with human perceptible colors is not simple. Which of the above approach generates diverse color set is yet to be tested.


I have manually found 8 most distinguishable colors as follows,

color = c("blue","red","green3","hotpink3","yellow","maroon1","lightsalmon3","black")

but if you need more, just see here and make your own list: http://www.stat.columbia.edu/~tzheng/files/Rcolor.pdf

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