I wish to present a distance matrix in an article I am writing, and I am looking for good visualization for it.

So far I came across balloon plots (I used it here, but I don't think it will work in this case), heatmaps (here is a nice example, but they don't allow to present the numbers in the table, correct me if I am wrong. Maybe half the table in colors and half with numbers would be cool) and lastly correlation ellipse plots (here is some code and example - which is cool to use a shape, but I am not sure how to use it here).

There are also various clustering methods but they will aggregate the data (which is not what I want) while what I want is to present all of the data.

Example data:

nba <- read.csv("http://datasets.flowingdata.com/ppg2008.csv")
dist(nba[1:20, -1], )

I am open for ideas.

  • Please come up with some dummy data, it's very hard to perceive what you're trying to get... I figured out (after very brief brainstorming session) that correlograms could be adequate? On lower.tri you can put scatterplots, on the upper.tri you can put correlation coefficients... But you already know that, right... O_o
    – aL3xa
    Commented Jun 21, 2010 at 1:46
  • What's wrong with a heatmap and a legend? Do you really have to comment all of the values in your distance matrix? Couldn't you just overlay the crucial values on the plot after?
    – nico
    Commented Jun 21, 2010 at 6:05
  • Hi aL3xa - correlograms will aggregate the data - which I am trying to avoid as much as possible (but thanks for the suggestion :) ). .... Dear Nico - that is a good question. If I had the option of only overlaying parts of the data I might use it. Yet again, I would need some help in how such a code can be written - thanks :)
    – Tal Galili
    Commented Jun 21, 2010 at 6:31
  • 2
    'dummy' data is not needed here--The OP has chosen the correct level of abstraction to present this Question. Data wouldn't clarify the question in any meaningful way (unless someone doesn't know what a distance matrix is nor how to calculate one). The question relates to any distance matrix, and it's faster for us to generate one in R than to copy it from the OP.
    – doug
    Commented Jun 21, 2010 at 8:47
  • 1
    Not the distances per se, but what about Multidimensional Scaling? Commented Jul 5, 2016 at 13:11

7 Answers 7


You could also use force-directed graph drawing algorithms to visualize a distance matrix, e.g.

nba <- read.csv("http://datasets.flowingdata.com/ppg2008.csv")
dist_m <- as.matrix(dist(nba[1:20, -1]))
dist_mi <- 1/dist_m # one over, as qgraph takes similarity matrices as input
jpeg('example_forcedraw.jpg', width=1000, height=1000, unit='px')
qgraph(dist_mi, layout='spring', vsize=3)

  • 5
    I like this solution very much, because it actually represents the distance. Do you really want the reciprocal 1/dist? Why not 1-dist? As far as I can see the dist is never > 1. Commented Sep 7, 2017 at 11:55
  • 1
    What does the line "dist_mi <- 1/dist_m" actually do? It doesn't assign the inverse matrix or a normalized matrix as with the rescale function. What is the meaning of that operation?
    – Kora K
    Commented Jan 3, 2020 at 16:12
  • 1
    What does line thickness represent here?
    – bob
    Commented Jun 8, 2022 at 14:03
  • Shouldn't dist_mi <- 1/dist_m be dist_mi <- 1/(dist_m + 1)? Commented Mar 3, 2023 at 20:58
  • This library is no longer avaible, any instalation process ends with "'RcppExports.o' does not exist". Any other libraries that makes something similar?
    – kwadratens
    Commented Sep 8, 2023 at 13:02

Tal, this is a quick way to overlap text over an heatmap. Note that this relies on image rather than heatmap as the latter offsets the plot, making it more difficult to put text in the correct position.

To be honest, I think this graph shows too much information, making it a bit difficult to read... you may want to write only specific values.

also, the other quicker option is to save your graph as pdf, import it in Inkscape (or similar software) and manually add the text where needed.

Hope this helps

nba <- read.csv("http://datasets.flowingdata.com/ppg2008.csv")

dst <- dist(nba[1:20, -1],)
dst <- data.matrix(dst)

dim <- ncol(dst)

image(1:dim, 1:dim, dst, axes = FALSE, xlab="", ylab="")

axis(1, 1:dim, nba[1:20,1], cex.axis = 0.5, las=3)
axis(2, 1:dim, nba[1:20,1], cex.axis = 0.5, las=1)

text(expand.grid(1:dim, 1:dim), sprintf("%0.1f", dst), cex=0.6)

enter image description here


A Voronoi Diagram (a plot of a Voronoi Decomposition) is one way to visually represent a Distance Matrix (DM).

They are also simple to create and plot using R--you can do both in a single line of R code.

If you're not famililar with this aspect of computational geometry, the relationship between the two (VD & DM) is straightforward, though a brief summary might be helpful.

Distance Matrices--i.e., a 2D matrix showing the distance between a point and every other point, are an intermediate output during kNN computation (i.e., k-nearest neighbor, a machine learning algorithm which predicts the value of a given data point based on the weighted average value of its 'k' closest neighbors, distance-wise, where 'k' is some integer, usually between 3 and 5.)

kNN is conceptually very simple--each data point in your training set is in essence a 'position' in some n-dimension space, so the next step is to calculate the distance between each point and every other point using some distance metric (e.g., Euclidean, Manhattan, etc.). While the training step--i.e., construcing the distance matrix--is straightforward, using it to predict the value of new data points is practically encumbered by the data retrieval--finding the closest 3 or 4 points from among several thousand or several million scattered in n-dimensional space.

Two data structures are commonly used to address that problem: kd-trees and Voroni decompositions (aka "Dirichlet tesselation").

A Voronoi decomposition (VD) is uniquely determined by a distance matrix--i.e., there's a 1:1 map; so indeed it is a visual representation of the distance matrix, although again, that's not their purpose--their primary purpose is the efficient storage of the data used for kNN-based prediction.

Beyond that, whether it's a good idea to represent a distance matrix this way probably depends most of all on your audience. To most, the relationship between a VD and the antecedent distance matrix will not be intuitive. But that doesn't make it incorrect--if someone without any statistics training wanted to know if two populations had similar probability distributions and you showed them a Q-Q plot, they would probably think you haven't engaged their question. So for those who know what they are looking at, a VD is a compact, complete, and accurate representation of a DM.

So how do you make one?

A Voronoi decomp is constructed by selecting (usually at random) a subset of points from within the training set (this number varies by circumstances, but if we had 1,000,000 points, then 100 is a reasonable number for this subset). These 100 data points are the Voronoi centers ("VC").

The basic idea behind a Voronoi decomp is that rather than having to sift through the 1,000,000 data points to find the nearest neighbors, you only have to look at these 100, then once you find the closest VC, your search for the actual nearest neighbors is restricted to just the points within that Voronoi cell. Next, for each data point in the training set, calculate the VC it is closest to. Finally, for each VC and its associated points, calculate the convex hull--conceptually, just the outer boundary formed by that VC's assigned points that are farthest from the VC. This convex hull around the Voronoi center forms a "Voronoi cell." A complete VD is the result from applying those three steps to each VC in your training set. This will give you a perfect tesselation of the surface (See the diagram below).

To calculate a VD in R, use the tripack package. The key function is 'voronoi.mosaic' to which you just pass in the x and y coordinates separately--the raw data, not the DM--then you can just pass voronoi.mosaic to 'plot'.

plot(voronoi.mosaic(runif(100), runif(100), duplicate="remove"))

enter image description here

  • 2
    Hello Doug, if I understand you correctly, then this is what I was hoping for - thank you! I looked at the function, and wanted to see if I understand what I need to do. I need to take the distance matrix, turn it into a long format, and then run the code on it? I looked at your explanation and the wiki page on the subject, and still am not sure how to interpret the plot for distance matrix. And further clarification would be great. Again thank you very very much for this lead! Best, Tal.
    – Tal Galili
    Commented Jun 22, 2010 at 9:16
  • 1
    Tal--it's actually easier than that (i edited my answer in light of your comment above). The function 'voronoi.mosaic' accepts two parameters, a vector of x-coordinates and a vector of y-coordinates. These are your Voronoi Centers--e.g., 100 data points selected at random from your initial data set. voronoi.mosaic does not accept a DM directly (though it's obviously a result from an intermediate step). When you make this diagram then, if you want, you can use the 'points' function to layer the rest of your data points.
    – doug
    Commented Jun 22, 2010 at 14:27
  • 4
    Hi Doug, thank you for replying. The dataset on which I intend to run this on has only 50 data points (items). However, for it I can only produce the distance matrix (I don't have a multi dimensional matrix on which the items exists). So my question is, given that I have only a distance matrix of (let's say) 50 items - can I produce a voronoi plot from it? Thanks for the help! Tal
    – Tal Galili
    Commented Jun 22, 2010 at 15:45

You may want to consider looking at a 2-d projection of your matrix (Multi Dimensional Scaling). Here is a link to how to do it in R.

Otherwise, I think you are on the right track with heatmaps. You can add in your numbers without too much difficulty. For example, building of off Learn R :

nba <- read.csv("http://datasets.flowingdata.com/ppg2008.csv")
nba$Name <- with(nba, reorder(Name, PTS))
nba.m <- melt(nba)
nba.m <- ddply(nba.m, .(variable), transform,
rescale = rescale(value))
(p <- ggplot(nba.m, aes(variable, Name)) + geom_tile(aes(fill = rescale),
colour = "white") + scale_fill_gradient(low = "white",
high = "steelblue")+geom_text(aes(label=round(rescale,1))))

enter image description here

  • Thank you Ian, very helpful! Can you think how to change what is displayed in the upper half of the matrix?
    – Tal Galili
    Commented Jun 21, 2010 at 5:50
  1. A dendrogram based on a hierarchical cluster analysis can be useful: http://www.statmethods.net/advstats/cluster.html

  2. A 2-D or 3-D multidimensional scaling analysis in R: http://www.statmethods.net/advstats/mds.html

  3. If you want to go into 3+ dimensions, you might want to explore ggobi / rggobi: http://www.ggobi.org/rggobi/

  • Hi Jeromy, thank you for the reply. I didn't know about the link in section 2 so it was interesting to come across. However, I am looking for a way to represent my data without reducing the dimensionality. Thanks in any case :) !
    – Tal Galili
    Commented Jun 21, 2010 at 5:45
  • The MDS is mathmatically optimal for this problem in the sense of MSE. However sometimes there are very dense clusters in the result which is "right" mathematically but not "proper" for visualization. Do you have any idea on this? Commented Aug 7, 2013 at 10:20

In the book "Numerical Ecology" by Borcard et al. 2011 they used a function called *coldiss.r * you can find it here: http://ichthyology.usm.edu/courses/multivariate/coldiss.R

it color codes the distances and even orders the records by dissimilarity.

another good package would be the seriation package.

Reference: Borcard, D., Gillet, F. & Legendre, P. (2011) Numerical Ecology with R. Springer.

enter image description here


A solution using Multidimensional Scaling

data = read.csv("http://datasets.flowingdata.com/ppg2008.csv", sep = ",")
dst = tcrossprod(as.matrix(data[,-1]))
dst = matrix(rep(diag(dst), 50L), ncol = 50L, byrow = TRUE) + 
  matrix(rep(diag(dst), 50L), ncol = 50L, byrow = FALSE) - 2*dst

mds = isoMDS(dst)
#remove {type = "n"} to see dots
plot(mds$points, type = "n", pch = 20, cex = 3, col = adjustcolor("black", alpha = 0.3), xlab = "X", ylab = "Y") 
text(mds$points, labels = rownames(data), cex = 0.75)

enter image description here

  • What is the meaning of X and Y? What is their measurement unit?
    – FaCoffee
    Commented Sep 13, 2018 at 16:25
  • @FaCoffee Principal components of the distance matrix (in the ordinary formulation of MDS). Commented Sep 13, 2018 at 16:29

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