# Rotate graph by angle

I have multiple matrices filled with the x and y coordinates of multiple points in 2D space that make up a graph. The matrices look something like this

x1 x2 x3 x4 ...
y1 y2 y3 y4 ...

A possible graph looks something like this

What I want to do is rotate the graph around point A so that the line between the points A and B are parallel to the X-Axis.

My idea was to treat the line AB as the hypothenuse of a right-triangle, calculate α (the angle at point A) and rotate the matrix for this graph by it using a rotation matrix.

What I did so far is the following

``````#df is the subset of my data that describes the graph we're handling right now,
#df has 2 or more rows

beginx=df[1,]\$xcord          #get the x coordinate of point A
beginy=df[1,]\$ycord          #get the y coordinate of point A
endx=df[nrow(df)-1,]\$xcord   #get the x coordinate of point B
endy=df[nrow(df)-1,]\$ycord   #get the y coordinate of point B
xnow=df\$xcord
ynow=df\$ycord
xdif=abs(beginx-endx)
ydif=abs(beginy-endy)

if((xdif != 0) & (ydif!=0)){
direct=sqrt(abs((xdif^2)-(ydif^2))) #calculate the length of the hypothenuse
sinang=abs(beginy-endy)/direct
angle=1/sin(sinang)
if(beginy>endy){
angle=angle
}else{
angle=360-angle
}
rotmat=rot(angle)    # use the function rot(angle) to get the rotation matrix for
# the calculated angle
A = matrix(c(xnow,ynow),nrow=2,byrow = TRUE)  # matrix containing the graph coords
admat=rotmat%*%A                          #multiply the matrix with the rotation matrix
}
``````

This approach fails because it isn't flexible enough to always calculate the needed angle with the result being that the graph is rotated by the wrong angle and / or in the wrong direction.

Thanks in advance for reading and hopefully some of you can bring some fresh ideas to this

Edit: Data to reproduce this can be found here

X-Coordinates

Y-Coordinates

Not sure how to provide the data you've asked for, I'll gladly provide it in another way if you specify how you'd like it

-
Please provide data. –  Roland Mar 17 at 17:23
Make smaller example data which demonstrates the problem, and paste the result of `dput` here. –  Matthew Lundberg Mar 17 at 17:40
I'll try to cut it down when I find the time, basically you could also just pick two random points in 2D space for A and B, that should suffice to reproduce the basic problem. –  Rickyfox Mar 17 at 17:45
This is rotation about point A, or rotation about the origin? –  Blue Magister Mar 17 at 17:52
added that, rotation should be about point A, the starting point –  Rickyfox Mar 17 at 18:02
show 1 more comment

Like this?

``````#read in X and Y as vectors
M <- cbind(X,Y)
#plot data
plot(M[,1],M[,2],xlim=c(0,1200),ylim=c(0,1200))
#calculate rotation angle
alpha <- -atan((M[1,2]-tail(M,1)[,2])/(M[1,1]-tail(M,1)[,1]))
#rotation matrix
rotm <- matrix(c(cos(alpha),sin(alpha),-sin(alpha),cos(alpha)),ncol=2)
#shift, rotate, shift back
M2 <- t(rotm %*% (
t(M)-c(M[1,1],M[1,2])
)+c(M[1,1],M[1,2]))
#plot
plot(M2[,1],M2[,2],xlim=c(0,1200),ylim=c(0,1200))
``````

# Edit:

I'll break down the transformation to make it easier to understand. However, it's just basic linear algebra.

``````plot(M,xlim=c(-300,1200),ylim=c(-300,1200))
#shift points, so that turning point is (0,0)
M2.1 <- t(t(M)-c(M[1,1],M[1,2]))
points(M2.1,col="blue")
#rotate
M2.2 <- t(rotm %*% (t(M2.1)))
points(M2.2,col="green")
#shift back
M2.3 <- t(t(M2.2)+c(M[1,1],M[1,2]))
points(M2.3,col="red")
``````

-
this looks good, I'll try it later and see if it works properly –  Rickyfox Mar 17 at 18:29
would you care to elaborate the following line in your code? M2 <- t(rotm %*% (t(M)-c(M[1,1],M[1,2]))+c(M[1,1],M[1,2])) –  Rickyfox Mar 29 at 11:24
Have you forgotten your lectures on linear algebra? If you need transformations like this more often, you should read an appropriate maths book. –  Roland Mar 29 at 13:04
Thanks for the explanation –  Rickyfox Mar 29 at 13:21

Instead of a data frame, it looks like your data is better served as a matrix (via `as.matrix`).

This answer very similar to Roland's, but breaks things down into more steps and has some special-case handling when the angle is a multiple of `pi/2`.

``````#sample data
set.seed(1) #for consistency of random-generated data
d <- matrix(c(sort(runif(50)),sort(runif(50))),ncol=2)

rotA <- function(d) {
d.offset <- apply(d,2,function(z) z - z[1]) #offset data
endpoint <- d.offset[nrow(d.offset),] #gets difference
rot <- function(angle) matrix(
c(cos(angle),-sin(angle),sin(angle),cos(angle)),nrow=2) #CCW rotation matrix
if(endpoint[2] == 0) {
return(d) #if y-diff is 0, then no action required
} else if (endpoint[1] == 0) {
rad <- pi/2 #if x-diff is 0, then rotate by a right angle