Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I have some data with some hard to deal with properties. There are two vectors that are taking a measure of quality (from 0-1) at points along a physical object. These measurements are indexed according to the distance the measurement was taken from the bottom of the object. Then, a quality improving transformation is applied to the object, and measurements are taken again. However, the number of measurements are not the same, nor are the points on which they are taken.

In R, the data looks something like this (but with many more points)

Before transformation:

     value index
[1,]   0.3     6
[2,]   0.6    16
[3,]   0.1    25
[4,]   0.8    37
[5,]   0.2    46
[6,]   0.4    58
[7,]   0.4    64
[8,]   0.2    76

After transformation:

      value index
 [1,]   0.3     1
 [2,]   0.5     9
 [3,]   0.7    18
 [4,]   0.4    30
 [5,]   0.9    44
 [6,]   0.3    48
 [7,]   0.4    61
 [8,]   0.5    66
 [9,]   0.3    76
[10,]   0.1    85

Under the assumption that quality along the object is continuous (if not observed at every point), and that the ammount of improvement during the tranformation is dependent on the point along the object, I would like to be able to show the distribution of quality improvement.

Since there are different numbers of measurements, and different indexes, I don't think

plot(density(after$value - before$value)) 

is what I'm looking for. My question is, is there a sane way to take that difference such that I have a number of observations for how much quality improved? Or am I going to be stuck looking at the difference in means?

share|improve this question
Also, if anyone can think of a better title, please change it. I don't know if this one captures my problem in the slightest. – Wilduck Dec 23 '10 at 16:29
Your values are samples of a continuous curve, so maybe you want to compare the total area under those curves. So the question is maybe how to best interpolate the two curves... – Spacedman Dec 23 '10 at 16:37
@Spacedman That may very well be my question. It's good to have some words to stick to my question (interpolate the curves). This will help with googleing for sure. – Wilduck Dec 23 '10 at 17:25
up vote 3 down vote accepted

Maybe this is what you want: you want to display a smoothed curve of Index vs Value for "before" the transformation and for "after" the transformation, on the same graph so you can visualize the general "improvement" in quality: I show this below with some simulated data.

bef <- .2 + 2*((1:1000)/1000 - .5)^2  + round(rnorm(1000),1)/100
aft <- bef * (1 + rnorm(1,.7,.2))
bef.samp <- sample(1:1000, 100)
aft.samp <- sample(1:1000, 60)
bef.df <- data.frame( value = bef[ bef.samp ], index = bef.samp )
aft.df <- data.frame( value = aft[ aft.samp ], index = aft.samp )
bef.aft <- rbind( cbind(when = 'bef', bef.df), cbind( when = 'aft', aft.df))
ggplot(bef.aft, aes(index,value)) + 
   geom_smooth(aes(colour = when), se=0, size=1) + 

alt text

share|improve this answer

Your Answer


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.