EDIT: I think, from my discussion below with @joran , that @joran helped me figure out *how* `dist`

is altering the distance value (it appears to be scaling the sum of the squares of the coordinates by the value [total dimensions]/[non-missing dimensions], but that is just a guess). What I'd like to know, if anyone does know, are: is that what is really going on? If so, why is that considered a reasonable thing to do? Can there, or should there be options to `dist`

to compute it the way I proposed (that question might be to vague or of an opinionated nature to answer, though).

I was wondering how the `dist`

function actually works on vectors that have missing values. Below is a recreated example. I use the `dist`

function and a more fundamental implementation of what I believe should be the definition of Euclidian distance with sqrt, sum, and powers. I also expected that if a component of either vector was `NA`

, that that dimension would just be thrown out of the sum, which is how I implemented it. But you can see that that definition doesn't agree with `dist`

.

I will be using my basic implementation to handle the `NA`

values, but I was wondering how `dist`

is actually arriving at a value when vectors have `NA`

, and why it doesn't agree with how I calculate it below. I would think that my basic implementation should be the default/common one, and I can't figure out what alternate method `dist`

is using to get what it is getting.

Thanks, Matt

```
v1 <- c(1,1,1)
v2 <- c(1,2,3)
v3 <- c(1,NA,3)
# Agree on vectors with non-missing components
# --------------------------------------------
dist(rbind(v1, v2))
# v1
# v2 2.236068
sqrt(sum((v1 - v2)^2, na.rm=TRUE))
# [1] 2.236068
# But they don't agree when there is a missing component
# Under what logic does sqrt(6) make sense as the answer for dist?
# --------------------------------------------
dist(rbind(v1, v3))
# v1
# v3 2.44949
sqrt(sum((v1 - v3)^2, na.rm=TRUE))
# [1] 2
```