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I have the following data

set.seed(11)
Data<-rbind(c(1:5),c(2:6))


Candidates <- matrix(1:25 + rnorm(25), ncol=5,
dimnames=list(NULL, paste0("x", 1:5)))
 colnames(Data)<-colnames(Candidates)

I want to subtract each row of my Data from each row of the Candidate matrix And return the minimal absolute difference So for row one I want to find out the smallest amount of error possible

sum(abs(Data[1,]-Candidates[1,]))
sum(abs(Data[1,]-Candidates[2,]))
sum(abs(Data[1,]-Candidates[3,]))
sum(abs(Data[1,]-Candidates[4,]))
sum(abs(Data[1,]-Candidates[5,]))

In this case it's 38.15826. At the moment I'm not actually interested in finding out which Candidate row results in the smallest absolute deviation, I just want to know the smallest absolute deviation for each Data row.

I would then like to end up with a new dataset which has my original Data and the smallest deviation, e.g. row one would like this:

x1 x2 x3 x4 x5 MinDev 
1  2  3  4  5  38.15826

My real Candidate Matrix is relatively small but my real Data is quite large, so at the moment I'm just building a loop that

Err[i,]<- min(rbinds( 
    sum(abs(Data[i,]-Candidates[1,])),
    sum(abs(Data[i,]-Candidates[2,]))...))

but I'm sure there's a better, more automated way to do this so that it can accomodate large Data matrices and Candidate matrices of different sizes.

Any ideas?

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1  
Make the example reproducible by using set.seed at the beginning. –  Nishanth Apr 21 '13 at 13:05
    
Edited original question, I had forgotten to define seed. Apologies –  Mercelo Apr 21 '13 at 13:05
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3 Answers

up vote 4 down vote accepted

You can use sweep, rowSums, and apply to automate this

sum(abs(Data[1,]-Candidates[1,]))  ## 38.15826

Testing on the first row of Data:

min(
    rowSums(abs(
                ## subtract row 1 of Data from each row of Candidates
                sweep(Candidates,2,Data[1,],"-"))))
## 38.15826

For convenience/readability, encapsulate this in a function:

getMinDev <- function(x) {
    min(rowSums(abs(sweep(Candidates,2,x,"-"))))
}

Now apply to each row of Data:

cbind(Data,MinDev=apply(Data,1,getMinDev))

There may be methods that are marginally faster than sweep (e.g. the matrix computations given in @e4e5f4's answer), but this should be a good baseline. I like sweep because it is descriptive and doesn't depend on knowing that R uses column-major matrix ordering.

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+1 for showing me a new function (sweep) today –  Nishanth Apr 21 '13 at 13:34
1  
(+1) sum(abs(vec1 - vec2)) is just the manhattan distance. dist(rbind(vec1, vec2), method = "manhattan") –  Arun Apr 21 '13 at 13:43
    
@Arun, why not post as answer? (Or edit my answer if you like.) –  Ben Bolker Apr 21 '13 at 13:48
    
@BenBolker, added an answer. –  Arun Apr 21 '13 at 14:29
    
Ben, this is great. Thanks –  Mercelo Apr 21 '13 at 14:44
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You can use apply with some matrix operations:

CalcMinDev <- function(x)
{
    m <- t(matrix(rep(x, nrow(Candidates)), nrow=nrow(Candidates)))
    min(rowSums(abs(m - Candidates)))
}

cbind(Data, MinDev=apply(Data, 1, CalcMinDev))
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3  
a bit shorter: CalcMinDev <- function(x)min(colSums(abs(t(Candidates) - x))) –  flodel Apr 21 '13 at 13:38
    
+1, I tried to avoid creating a matrix, but I got lost in t() - colSums - rowSums –  Nishanth Apr 21 '13 at 13:52
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Following @BenBolker's suggestion to turn my comment (using dist function with method="manhattan") to an answer:

The idea: The trick is that if you supply a matrix to dist, it'll return the distance of all combinations back as a lower triangular matrix.

dist(rbind(Candidates, Data), method="manhattan")
#           1         2         3         4         5         6
# 2  8.786827                                                  
# 3 11.039044  3.718396                                        
# 4 16.120267  7.333440  6.041076                              
# 5 21.465682 12.678855 10.426638  5.345415                    
# 6 38.158256 45.763021 48.015238 53.096461 58.441876          
# 7 35.158256 40.763021 44.048344 48.096461 53.441876  5.000000

Here, 6th row and the 7th row (from index 1 to 5) are the distances you're interested in. So, basically, you'll just have to calculate indices to extract the elements you're interested.


The final code would look like:

idx1 <- seq_len(nrow(Data)) + nrow(Candidates)
idx2 <- seq_len(ncol(Candidates))
tt <- dist(rbind(Candidates, Data), method="manhattan")
transform(Data, minDev = apply(as.matrix(tt)[idx1, idx2], 1, min))
#   x1 x2 x3 x4 x5   minDev
# 6  1  2  3  4  5 38.15826
# 7  2  3  4  5  6 35.15826
share|improve this answer
    
Arun, thank you –  Mercelo Apr 21 '13 at 14:43
    
Instead of computing a whole distance matrix, you can use apply to compute the distances just for the combinations you require, of course. –  Arun Apr 21 '13 at 14:54
    
Really nice, this is great. I had actually the same thing before, and I solved it using sweep, but this is a lot better (I had used the eucl space and manhattan both). –  PascalvKooten Apr 21 '13 at 18:49
    
One question though, would it be possible somehow to weigh certain deviations more, before it sums all the deviances? –  PascalvKooten Apr 21 '13 at 18:50
    
@Dualinity, the dist function calls C_Cdist (C code). And there seems to be no options for this. Depending on the method, it may be possible to multiply the weights before calculating distance or so (not tested). But I agree such an option will be handy. –  Arun Apr 21 '13 at 20:39
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