What the most efficient way in the programming language R to calculate the angle between two vectors?
9 Answers
According to page 5 of this PDF, sum(a*b)
is the R command to find the dot product of vectors a
and b
, and sqrt(sum(a * a))
is the R command to find the norm of vector a
, and acos(x)
is the R command for the arccosine. It follows that the R code to calculate the angle between the two vectors is
theta < acos( sum(a*b) / ( sqrt(sum(a * a)) * sqrt(sum(b * b)) ) )

Really helpful answer, I would expect R to have a function to compute the norm of a vector and the dot product (as Matlab does) but I coudn't find it anywhere. I also wanted to compute the cos between two vectors, so this solved my problem. PS: +1 for source, the PDF file is quite good indeed.– skdNov 14, 2011 at 21:59

Hello! I am trying to access the pdf but its forbidden. Anyone of you have a copy of this doc? Thanks :)– Kaye11Jul 1, 2013 at 10:27


1The cosine is only monotone on the interval (0, pi), so the result might not be what you expect for angles greater than pi. Feb 13, 2015 at 13:30

2@user1965813 Agreed. The
atan2
function is the way to go (see my answer). Jul 26, 2015 at 22:02
My answer consists of two parts. Part 1 is the math  to give clarity to all readers of the thread and to make the R code that follows understandable. Part 2 is the R programming.
Part 1  Math
The dot product of two vectors x and y can be defined as:
where x is the Euclidean norm (also known as the L_{2} norm) of the vector x.
Manipulating the definition of the dot product, we can obtain:
where theta is the angle between the vectors x and y expressed in radians. Note that theta can take on a value that lies on the closed interval from 0 to pi.
Solving for theta itself, we get:
Part 2  R Code
To translate the mathematics into R code, we need to know how to perform two matrix (vector) calculations; dot product and Euclidean norm (which is a specific type of norm, known as the L_{2} norm). We also need to know the R equivalent of the inverse cosine function, cos^{1}.
Starting from the top. By reference to ?"%*%"
, the dot product (also referred to as the inner product) can be calculated using the %*%
operator. With reference to ?norm
, the norm()
function (base package) returns a norm of a vector. The norm of interest here is the L_{2} norm or, in the parlance of the R help documentation, the "spectral" or "2"norm. This means that the type
argument of the norm()
function ought to be set equal to "2"
. Lastly, the inverse cosine function in R is represented by the acos()
function.
Solution
Equipped with both the mathematics and the relevant R functions, a prototype function (that is, not production standard) can be put together  using Base package functions  as shown below. If the above information makes sense then the angle()
function that follows should be clear without further comment.
angle < function(x,y){
dot.prod < x%*%y
norm.x < norm(x,type="2")
norm.y < norm(y,type="2")
theta < acos(dot.prod / (norm.x * norm.y))
as.numeric(theta)
}
Test the function
A test to verify that the function works. Let x = (2,1) and y = (1,2). Dot product between x and y is 4. Euclidean norm of x is sqrt(5). Euclidean norm of y is also sqrt(5). cos theta = 4/5. Theta is approximately 0.643 radians.
x < as.matrix(c(2,1))
y < as.matrix(c(1,2))
angle(t(x),y) # Use of transpose to make vectors (matrices) conformable.
[1] 0.6435011
I hope this helps!

3Always like answers that include the math behind them! Also +1 for using
norm
. The amount of times I've seensqrt(a * a)
.....– wspurginMar 31, 2016 at 20:15
For 2Dvectors, the way given in the accepted answer and other ones does not take into account the orientation (the sign) of the angle (angle(M,N)
is the same as angle(N,M)
) and it returns a correct value only for an angle between 0
and pi
.
Use the atan2
function to get an oriented angle and a correct value (modulo 2pi
).
angle < function(M,N){
acos( sum(M*N) / ( sqrt(sum(M*M)) * sqrt(sum(N*N)) ) )
}
angle2 < function(M,N){
atan2(N[2],N[1])  atan2(M[2],M[1])
}
Check that angle2
gives the correct value:
> theta < seq(2*pi, 2*pi, length.out=10)
> O < c(1,0)
> test1 < sapply(theta, function(theta) angle(M=O, N=c(cos(theta),sin(theta))))
> all.equal(test1 %% (2*pi), theta %% (2*pi))
[1] "Mean relative difference: 1"
> test2 < sapply(theta, function(theta) angle2(M=O, N=c(cos(theta),sin(theta))))
> all.equal(test2 %% (2*pi), theta %% (2*pi))
[1] TRUE

1@baptiste I don't see what is an oriented angle in 3D without involving an orientation for the plane containing the two vectors. My answer is specific to 2D. I'm going to edit it to emphasize this. Thank you for the remark. Jul 26, 2015 at 23:03

Something seems not right here. For example,
v1 < c(1, 1)
andv2 < c(1, 0.5)
, thenangle2(v1, v2)
gives3.463343
andangle(v1, v2)
gives2.819842
.– JACKY88Jul 14, 2016 at 14:39 
1@PatrickLi These two values are equal modulo 2pi :
> 3.463343 %% (2*pi) [1] 2.819842
Jul 14, 2016 at 16:10
You should use the dot product. Say you have V₁ = (x₁, y₁, z₁) and V₂ = (x₂, y₂, z₂), then the dot product, which I'll denote by V₁·V₂, is calculated as
V₁·V₂ = x₁·x₂ + y₁·y₂ + z₁·z₂ = V₁ · V₂ · cos(θ);
What this means is that that sum shown on the left is equal to the product of the absolute values of the vectors times the cosine of the angle between the vectors. the absolute value of the vectors V₁ and V₂ are calculated as
V₁ = √(x₁² + y₁² + z₁²), and
V₂ = √(x₂² + y₂² + z₂²),
So, if you rearrange the first equation above, you get
cos(θ) = (x₁·x₂ + y₁·y₂ + z₁·z₂) ÷ (V₁·V₂),
and you just need the arccos function (or inverse cosine) applied to cos(θ) to get the angle.
Depending on your arccos function, the angle may be in degrees or radians.
(For two dimensional vectors, just forget the zcoordinates and do the same calculations.)
Good luck,
John Doner

2where is the dot product in R? That is such a basic/common operation that it seems out of sorts to need to code it. I have seen some noise about sum(a*b) being the dot product: but what is the R idiomatic way? Jan 19, 2016 at 5:33

@javadba you can either use
sum(a * b)
ora %*% b
. The latter is a more general operator that upgrades the inputs to matrices (row vector and column vector) and returns a 1x1 matrix as the result. Aug 2, 2019 at 19:09
if you install/upload the library(matlib): there is a function called angle(x, y, degree = TRUE) where x and y are vectors. Note: if you have x and y in matrix form, use as.vector(x) and as.vector(y):
library(matlib)
matA < matrix(c(3, 1), nrow = 2) ##column vectors
matB < matrix(c(5, 5), nrow = 2)
angle(as.vector(matA), as.vector(matB))
##default in degrees, use degree = FALSE for radians
Another solution : the correlation between the two vectors is equal to the cosine of the angle between two vectors.
so the angle can be computed by acos(cor(u,v))
# example u(1,2,0) ; v(0,2,1)
cor(c(1,2),c(2,1))
theta = acos(cor(c(1,2),c(2,1)))

1That is not correct. The angle between (1, 2) and (2,1) is 0.643 rad, but your method gives pi radians.– zoc99Jun 15, 2021 at 1:12
The traditional approach to obtaining an angle between two vectors (i.e. acos(sum(a*b) / (sqrt(sum(a*a)) * sqrt(sum(b*b))))
, as presented in some of the other answers) suffers from numerical instability in several corner cases. The following code works for ndimensions and in all corner cases (it doesn't check for zero length vectors, but that's easy to add). See notes below.
# Get angle between two ndimensional vectors
angle_btw < function(v1, v2) {
signbit < function(x) {
x < 0
}
u1 < v1 / norm(v1, "2")
u2 < v2 / norm(v2, "2")
y < u1  u2
x < u1 + u2
a0 < 2 * atan(norm(y, "2") / norm(x, "2"))
if (!(signbit(a0)  signbit(pi  a0))) {
a < a0
} else if (signbit(a0)) {
a < 0.0
} else {
a < pi
}
a
}
This code is adapted from a Julia implementation by Jeffrey Sarnoff (MIT license), in turn based on these notes by Prof. W. Kahan (page 15).
I think what you need is an inner product. For two vectors v,u
(in R^n
or any other innerproduct spaces) <v,u>/vu= cos(alpha)
. (were alpha
is the angle between the vectors)
for more details see:
If you want to calculate the angle among multiple variables, you can use the following function, which is an extension of the solution provided by @Graeme Walsh.
angles < function(matrix){
## Calculate the crossproduct of the matrix
cross.product < t(matrix)%*%matrix
## the lower and the upper triangle of the crossproduct is the dot products among vectors
dot.products< cross.product[lower.tri(cross.product)]
## Calculate the L2 norms
temp < suppressWarnings(diag(sqrt(cross.product)))
temp < temp%*%t(temp)
L2.norms < temp[lower.tri(temp)]
## Arccosine values for each pair of variables
lower.t < acos(dot.products/L2.norms)
## Create an empty matrix to present the results
result.matrix < matrix(NA,ncol = dim(matrix)[2],nrow=dim(matrix)[2])
## Fill the matrix with arccosine values and assign the diagonal values as zero “0”
result.matrix[lower.tri(result.matrix)] < lower.t
diag(result.matrix) < 0
result.matrix[upper.tri(result.matrix)] < t(result.matrix)[upper.tri(t(result.matrix))]
## Get the result matrix
return(result.matrix)
}
In addition, if you meancentered your input variables and get the cosine values of the result matrix provided above, you will get the exact correlation matrix of the variables.
Here is an application of the function.
set.seed(123)
n < 100
m < 5
# Generate a set of random variables
mt < matrix(rnorm(n*m),nrow = n,ncol = m)
# Meancentered matrix
mt.c < scale(mt,scale = F)
# Cosine angles
cosine.angles < angles(matrix = mt)
> cosine.angles
[,1] [,2] [,3] [,4] [,5]
[1,] 0.000000 1.630819 1.686037 1.618119 1.751859
[2,] 1.630819 0.000000 1.554695 1.523353 1.712214
[3,] 1.686037 1.554695 0.000000 1.619723 1.581786
[4,] 1.618119 1.523353 1.619723 0.000000 1.593681
[5,] 1.751859 1.712214 1.581786 1.593681 0.000000
# Centereddata cosine angles
centered.cosine.angles < angles(matrix = mt.c)
> centered.cosine.angles
[,1] [,2] [,3] [,4] [,5]
[1,] 0.000000 1.620349 1.700334 1.614890 1.764721
[2,] 1.620349 0.000000 1.540213 1.526950 1.701793
[3,] 1.700334 1.540213 0.000000 1.615677 1.595647
[4,] 1.614890 1.526950 1.615677 0.000000 1.590057
[5,] 1.764721 1.701793 1.595647 1.590057 0.000000
# This will give you correlation matrix
cos(angles(matrix = mt.c))
[,1] [,2] [,3] [,4] [,5]
[1,] 1.00000000 0.04953215 0.12917601 0.04407900 0.19271110
[2,] 0.04953215 1.00000000 0.03057903 0.04383271 0.13062219
[3,] 0.12917601 0.03057903 1.00000000 0.04486571 0.02484838
[4,] 0.04407900 0.04383271 0.04486571 1.00000000 0.01925986
[5,] 0.19271110 0.13062219 0.02484838 0.01925986 1.00000000
# Orginal correlation matrix
cor(mt)
[,1] [,2] [,3] [,4] [,5]
[1,] 1.00000000 0.04953215 0.12917601 0.04407900 0.19271110
[2,] 0.04953215 1.00000000 0.03057903 0.04383271 0.13062219
[3,] 0.12917601 0.03057903 1.00000000 0.04486571 0.02484838
[4,] 0.04407900 0.04383271 0.04486571 1.00000000 0.01925986
[5,] 0.19271110 0.13062219 0.02484838 0.01925986 1.00000000
# Check whether they are equal
all.equal(cos(angles(matrix = mt.c)),cor(mt))
[1] TRUE