What is R's crossproduct function?

I feel stupid asking, but what is the intent of R's `crossprod` function with respect to vector inputs? I wanted to calculate the cross-product of two vectors in Euclidean space and mistakenly tried using `crossprod` .
One definition of the vector cross-product is `N = |A|*|B|*sin(theta)` where theta is the angle between the two vectors. (The direction of `N` is perpendicular to the A-B plane). Another way to calculate it is `N = Ax*By - Ay*Bx` .
`base::crossprod` clearly does not do this calculation, and in fact produces the vector dot-product of the two inputs `sum(Ax*Bx, Ay*By)`.

So, I can easily write my own `vectorxprod(A,B)` function, but I can't figure out what `crossprod` is doing in general.

• See the `crossprod` documentation- `Vectors are promoted to single-column or single-row matrices, depending on the context.`. Commented Mar 1, 2013 at 16:54
• @DavidRobinson I did read that, so I guess my question morphs into: what's a proper definition for a matrix cross-product and why isn't it like a Euclidean vector cross-product? Commented Mar 1, 2013 at 18:45
• @CarlWitthoft Thanks for posting this, I had the same question and it has driven me crazy. If you wrote `vectorxprod(A, B)` would you be willing to share (I guess as an answer)? Thx. Commented Jun 4, 2013 at 15:07
• @BryanHanson OK, see new answer. Commented Jun 4, 2013 at 15:23
• A bit late, but use of the term "cross product" to refer to the X'X matrix is fairly common in statistics (which is, after all, where R came from). This is a standard construction in regression applications. Googling "sum of squares and cross products" may help. Commented Jun 4, 2013 at 15:27

According to the help function in R: crossprod (X,Y) = t(X)%*% Y is a faster implementation than the expression itself. It is a function of two matrices, and if you have two vectors corresponds to the dot product. @Hong-Ooi's comments explains why it is called crossproduct.

• I'm going to check this answer as accepted and walk away slowly. After some searching, I found a monograph which actually does define a "matrix cross product" in the way R does. utdallas.edu/~herve/abdi-MatrixAlgebra2010-pretty.pdf Commented Mar 5, 2013 at 14:58

Here is a short code snippet which works whenever the cross product makes sense: the 3D version returns a vector and the 2D version returns a scalar. If you just want simple code that gives the right answer without pulling in an external library, this is all you need.

``````# Compute the vector cross product between x and y, and return the components
# indexed by i.
CrossProduct3D <- function(x, y, i=1:3) {
# Project inputs into 3D, since the cross product only makes sense in 3D.
To3D <- function(x) head(c(x, rep(0, 3)), 3)
x <- To3D(x)
y <- To3D(y)

# Indices should be treated cyclically (i.e., index 4 is "really" index 1, and
# so on).  Index3D() lets us do that using R's convention of 1-based (rather
# than 0-based) arrays.
Index3D <- function(i) (i - 1) %% 3 + 1

# The i'th component of the cross product is:
# (x[i + 1] * y[i + 2]) - (x[i + 2] * y[i + 1])
# as long as we treat the indices cyclically.
return (x[Index3D(i + 1)] * y[Index3D(i + 2)] -
x[Index3D(i + 2)] * y[Index3D(i + 1)])
}

CrossProduct2D <- function(x, y) CrossProduct3D(x, y, i=3)
``````

Does it work?

Let's check a random example I found online:

``````> CrossProduct3D(c(3, -3, 1), c(4, 9, 2)) == c(-15, -2, 39)
[1] TRUE TRUE TRUE
``````

Looks pretty good!

Why is this better than previous answers?

• It's 3D (Carl's was 2D-only).
• It's simple and idiomatic.
• Nicely commented and formatted; hence, easy to understand

The downside is that the number '3' is hardcoded several times. Actually, this isn't such a bad thing, since it highlights the fact that the vector cross product is purely a 3D construct. Personally, I'd recommend ditching cross products entirely and learning Geometric Algebra instead. :)

• Nice, tho' I'd take a bit of exception to the dumping cross products, since chirality is pretty important to E&M and a few other bits of physics :-) Commented Feb 12, 2014 at 20:11
• Thanks for the kind words :) Chirality is important, but the cross product's chirality is arbitrary. In E&M, you'd get all the same answers if you used a left hand rule, since it's applied an even number of times. See av8n.com/physics/pierre-puzzle.htm (and especially the solution) for more detail. Commented Feb 12, 2014 at 21:12

The help `?crossprod` explains it quite clearly. Take linear regression for example, for a model `y = XB + e` you want to find `X'X`, the product of `X` transpose and `X`. To get that, a simple call will suffice: `crossprod(X)` is the same as `crossprod(X,X)` is the same as `t(X) %*% X`. Also, `crossprod` can be used to find the dot product of two vectors.

• Yes, but that's not the definition of a cross product, as I said above. Maybe I'm being pedantic, but I'd like a "cross product" function to produce the result shown on the Wikipedia page (or your friendly neighborhood Physics 101 text :-) ) Commented Mar 1, 2013 at 20:03
• I have not heard it be called a cross product except in R. Commented Mar 1, 2013 at 21:59

In response to @Bryan Hanson's request, here's some Q&D code to calculate a vector crossproduct for two vectors in the plane. It's a bit messier to calculate the general 3-space vector crossproduct, or to extend to N-space. If you need those, you'll have to go to Wikipedia :-) .

``````crossvec <- function(x,y){
cv <-  x[1]*y[2]-x[2]*y[1]
return(invisible(cv))
}
``````
• Thanks @Carlwitthoft. I had written pretty much just that, and was hoping you had the 3d version. I shall write it and post it when it is ready. It's very strange that such a thing is not built in. It's extraordinarily common. Commented Jun 4, 2013 at 16:30
• There is a 3D version in `RFOC::cross.prod`; in the same package there a few others that accept different input and output formats. Also, `RSEIS::xprod`. Commented Jun 4, 2013 at 16:46
• @BryanHanson I suspect that, while 3D crossproduct is very common in Physics and Engineering, not so much in Statistical Analysis, which is sort of where `R` was born. Luckily, us Physicists are really good at turning equations into code :-) Commented Jun 4, 2013 at 17:02

Here is a minimalistic implementation for 3D vectors:

``````vector.cross <- function(a, b) {
if(length(a)!=3 || length(b)!=3){
stop("Cross product is only defined for 3D vectors.");
}
i1 <- c(2,3,1)
i2 <- c(3,1,2)
return (a[i1]*b[i2] - a[i2]*b[i1])
}
``````

If you want to get the scalar "cross product" of 2D vectors `u` and `v`, you can do

``````vector.cross(c(u,0),c(v,0))[3]
``````
• Except cross product is defined for 2D vectors so your msg is misleading. Why not merge our answers into a single function? Commented Mar 24, 2016 at 14:42
• @CarlWitthoft I know what you mean but cross product is technically 3D. If someone wants to wrap the special case (last line of this answer) in a function it is better they name it themselves. Commented Mar 24, 2016 at 15:50

There is a useful math operations package named pracma (https://rdrr.io/rforge/pracma/api/ or CRAN https://cran.r-project.org/web/packages/pracma/index.html). Easy to use and quick. The cross product is literally given by pracma::cross(x, y) for any two vectors.

• You should provide the link to CRAN rather than dev locations. Further, you need to identify the specific calls (functions) in `pracma` which meet the OP's needs Commented May 23, 2022 at 12:25
• I edited it. I don't agree with linking to CRAN instead of the link I had, since it is much more informative and points to all the different options the package holds. Commented May 24, 2022 at 13:10