# Find minimum deviation from vector from a matrix of possible vectors

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?

-
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

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.

-
+1 for showing me a new function (`sweep`) today –  Nishanth Apr 21 '13 at 13:34
(+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
Ben, this is great. Thanks –  Mercelo Apr 21 '13 at 14:44

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
``````
-
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

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))
``````
-
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