I'd like to have a straight forward C# function to get a closest point (from a point P) to a line-segment, AB. An abstract function may look like this. I've search through SO but not found a usable (by me) solution.
public Point getClosestPointFromLine(Point A, Point B, Point P);
Here's Ruby disguised as Pseudo-Code, assuming Point objects each have a x and y field.
def GetClosestPoint(A, B, P)
a_to_p = [P.x - A.x, P.y - A.y] # Storing vector A->P
a_to_b = [B.x - A.x, B.y - A.y] # Storing vector A->B
atb2 = a_to_b[0]**2 + a_to_b[1]**2 # **2 means "squared"
# Basically finding the squared magnitude
# of a_to_b
atp_dot_atb = a_to_p[0]*a_to_b[0] + a_to_p[1]*a_to_b[1]
# The dot product of a_to_p and a_to_b
t = atp_dot_atb / atb2 # The normalized "distance" from a to
# your closest point
return Point.new( :x => A.x + a_to_b[0]*t,
:y => A.y + a_to_b[1]*t )
# Add the distance to A, moving
# towards B
end
Alternatively:
From Line-Line Intersection, at Wikipedia. First, find Q, which is a second point that is to be had from taking a step from P in the "right direction". This gives us four points.
def getClosestPointFromLine(A, B, P)
a_to_b = [B.x - A.x, B.y - A.y] # Finding the vector from A to B
This step can be combined with the next
perpendicular = [ -a_to_b[1], a_to_b[0] ]
# The vector perpendicular to a_to_b;
This step can also be combined with the next
Q = Point.new(:x => P.x + perpendicular[0], :y => P.y + perpendicular[1])
# Finding Q, the point "in the right direction"
# If you want a mess, you can also combine this
# with the next step.
return Point.new (:x => ((A.x*B.y - A.y*B.x)*(P.x - Q.x) - (A.x-B.x)*(P.x*Q.y - P.y*Q.x)) / ((A.x - B.x)*(P.y-Q.y) - (A.y - B.y)*(P.y-Q.y)),
:y => ((A.x*B.y - A.y*B.x)*(P.y - Q.y) - (A.y-B.y)*(P.x*Q.y - P.y*Q.x)) / ((A.x - B.x)*(P.y-Q.y) - (A.y - B.y)*(P.y-Q.y)) )
end
Caching, Skipping steps, etc. is possible, for performance reasons.
if anyone is interested in a C# XNA function based on the above:
public static Vector2 GetClosestPointOnLineSegment(Vector2 A, Vector2 B, Vector2 P)
{
Vector2 AP = P - A; //Vector from A to P
Vector2 AB = B - A; //Vector from A to B
float magnitudeAB = AB.LengthSquared(); //Magnitude of AB vector (it's length squared)
float ABAPproduct = Vector2.Dot(AP, AB); //The DOT product of a_to_p and a_to_b
float distance = ABAPproduct / magnitudeAB; //The normalized "distance" from a to your closest point
if (distance < 0) //Check if P projection is over vectorAB
{
return A;
}
else if (distance > 1) {
return B;
}
else
{
return A + AB * distance;
}
}
points must form a closed linestringI guess I can Use this method but I don't know how can I use this? @BrainSlugs83
May 1, 2023 at 13:23
Your point (X) will be a linear combination of points A and B:
X = k A + (1-k) B
For X to be actually on the line segment, the parameter k must be between 0 and 1, inclusive. You can compute k as follows:
k_raw = (P-B).(A-B) / (A-B).(A-B)
(where the period denotes the dot product)
Then, to make sure the point is actually on the line segment:
if k_raw < 0:
k= 0
elif k_raw > 1:
k= 1
else:
k= k_raw
The answer from Justin L. is almost fine, but it doesn't check if the normalized distance is less than 0, or higher than the AB vector magnitude. Then it won't work well when P vector proyection is out of bounds (from the line segment AB). Here's the corrected pseudocode:
function GetClosestPoint(A, B, P)
{
vectorAP = (p.x - a.x, p.y - a.y) //Vector from A to P
vectorAB = (b.x - a.x, b.y - a.y) //Vector from A to B
magnitudeAB = vectorAB[0]^2 + vectorAB[1]^2
//Magnitude of AB vector (it's length)
ABAPproduct = vectorAB[0]*vectorAP[0] + vectorAB[1]*vectorAP[1]
//The product of a_to_p and a_to_b
distance = ABAPproduct / magnitudeAB
//The normalized "distance" from a to your closest point
if ( distance < 0) //Check if P projection is over vectorAB
{
returnPoint.x = a.x
returnPoint.y = a.y
}
else if (distance > magnitudeAB)
{
returnPoint.x = b.x
returnPoint.y = b.y
}
else
{
returnPoint.x = a.x + vectorAB[0]*distance
returnPoint.y = a.y + vectorAB[1]*distance
}
}
I wrote this a long time ago, it's not much different to what others have said, but it's a copy/paste solution in C# if you have a class (or struct) named PointF with members X and Y:
private static PointF ClosestPointToSegment(PointF P, PointF A, PointF B)
{
PointF a_to_p = new PointF(), a_to_b = new PointF();
a_to_p.X = P.X - A.X;
a_to_p.Y = P.Y - A.Y; // # Storing vector A->P
a_to_b.X = B.X - A.X;
a_to_b.Y = B.Y - A.Y; // # Storing vector A->B
float atb2 = a_to_b.X * a_to_b.X + a_to_b.Y * a_to_b.Y;
float atp_dot_atb = a_to_p.X * a_to_b.X + a_to_p.Y * a_to_b.Y; // The dot product of a_to_p and a_to_b
float t = atp_dot_atb / atb2; // # The normalized "distance" from a to the closest point
return new PointF(A.X + a_to_b.X * t, A.Y + a_to_b.Y * t);
}
Update: Looking at the comments it looks like I adapted it to C# from the same source code mentioned in the accepted answer.
if (t > 1) t = 1; if (t < 0) t = 0; to make sure that the point really lies on the segment
Find the slope a1 of AB by dividing the y-difference with the x-difference; then draw a perpendicular line (with slope a2 = -1/a1, you need to solve for the offset (b2) by putting P's coordinates into y = a2*x + b2); then you have two lines (i.e. two linear equations), and you need to solve the intersection. That will be your closest point.
Do the math right, and the function will be pretty trivial to write.
To elaborate a bit:
Original line:
y = a1 * x + b1
a1 = (By - Ay) / (Bx - Ax) <--
b1 = Ay - a1 * Ax <--
Perpendicular line:
y = a2 * x + b2
a2 = -1/a1 <--
b2 = Py - a2 * Px <--
Now you have P which lies on both lines:
y = a1 * x + b1
y = a2 * x + b2
--------------- subtract:
0 = (a1 - a2) * Px + (b1 - b2)
x = - (b1 - b2) / (a1 - a2) <--
y = a1 * x + b1 <--
Hope I didn't mess up somewhere :) UPDATE Of course I did. Serve me right for not working things out on paper first. I deserved every downvote, but I'd've expected someone to correct me. Fixed (I hope).
Arrows point the way.
UPDATE Ah, the corner cases. Yeah, some languages don't handle infinities well. I did say the solution was language-free...
You can check the special cases, they're quite easy. The first one is when the x difference is 0. That means the line is vertical, and the closest point is on a horizontal perpendicular. Thus, x = Ax, y = Px.
The second one is when y difference is 0, and the opposite is true. Thus, x = Px, y = Ay
Py with P.Y, add proper declarations and the like).
This answer is based on ideas from projective geometry.
Compute the cross product (Ax,Ay,1)×(Bx,By,1)=(u,v,w). The resulting vector describes the line connecting A and B: it has the equation ux+vy+w=0. But you can also interpret (u,v,0) as a point infinitely far away in a direction perpendicular to that line. Doing another cross product you get the line joining hat point to P: (u,v,0)×(Px,Py,1). And to intersect that line with the line AB, you do another cross product: ((u,v,0)×(Px,Py,1))×(u,v,w). The result will be a homogenous coordinate vector (x,y,z) from which you can read the coordinates of this closest point as (x/z,y/z).
Take everything together and you get the following formula:
Using a computer algebra system, you can find the resulting coordinates to be the following:
x = ((Ax - Bx)*Px + (Ay - By)*Py)*(Ax - Bx) + (Ay*Bx - Ax*By)*(Ay - By)
y = -(Ay*Bx - Ax*By)*(Ax - Bx) + ((Ax - Bx)*Px + (Ay - By)*Py)*(Ay - By)
z = (Ax - Bx)^2 + (Ay - By)^2
As you notice, there are a lot of recurring terms. Inventing (pretty much arbitrary) names for these, you can get the following final result, written in pseudocode:
dx = A.x - B.x
dy = A.y - B.y
det = A.y*B.x - A.x*B.y
dot = dx*P.x + dy*P.y
x = dot*dx + det*dy
y = dot*dy - det*dx
z = dx*dx + dy*dy
zinv = 1/z
return new Point(x*zinv, y*zinv)
Benefits of this approach:
Here are extension methods that should do the trick:
public static double DistanceTo(this Point from, Point to)
{
return Math.Sqrt(Math.Pow(from.X - to.X, 2) + Math.Pow(from.Y - to.Y, 2));
}
public static double DistanceTo(this Point point, Point lineStart, Point lineEnd)
{
double tI = ((lineEnd.X - lineStart.X) * (point.X - lineStart.X) + (lineEnd.Y - lineStart.Y) * (point.Y - lineStart.Y)) / Math.Pow(lineStart.DistanceTo(lineEnd), 2);
double dP = ((lineEnd.X - lineStart.X) * (point.Y - lineStart.Y) - (lineEnd.Y - lineStart.Y) * (point.X - lineStart.X)) / lineStart.DistanceTo(lineEnd);
if (tI >= 0d && tI <= 1d)
return Math.Abs(dP);
else
return Math.Min(point.DistanceTo(lineStart), point.DistanceTo(lineEnd));
}
Then just call:
P.DistanceTo(A, B);
To get distance of point "P" from line |AB|. It should be easy to modify this for PointF.
Finding the closest point then is just a matter of searching minimal distance. LINQ has methods for this.
The closest point C will be on a line whose slope is the reciprocal of AB and which intersects with P. This sounds like it might be homework, but I'll give some pretty strong hints, in order of increasing spoiler-alert level:
There can be only one such line.
This is a system of two line equations. Just solve for x and y.
Draw a line segment between A and B; call this L. The equation for L is y = mx + b, where m is the ratio of the y-coordinates to the x-coordinates. Solve for b using either A or B in the expression.
Do the same as above, but for CP. Now solve the simultaneous linear system of equations.
A Google search will give you a bevy of examples to choose from.
In case somebody is looking for a way to do this with Java + LibGdx:
Intersector.nearestSegmentPoint
This is the right algorythm to get nearest point of a segment from a point(Tested)(vb.net)
s2 = ClosestPointToSegment(point_x, Point_y, Segment_start_x, Segment_start_y, Segment_end_X, Segment_end_Y)
Public Shared Function DistanceTo(x1 As Double, y1 As Double, x2 As Double, y2 As Double) As Double
Return Math.Sqrt(Math.Pow(x1 - x2, 2) + Math.Pow(y1 - y2, 2))
End Function
Public Shared Function DistanceTo(point_x As Double, point_y As Double, lineStart_x As Double, lineStart_y As Double, lineEnd_x As Double, lineEnd_y As Double) As Double
Dim tI As Double = ((lineEnd_x - lineStart_x) * (point_x - lineStart_x) + (lineEnd_y - lineStart_y) * (point_y - lineStart_x)) / Math.Pow(DistanceTo(lineStart_x, lineStart_y, lineEnd_x, lineEnd_y), 2)
Dim dP As Double = ((lineEnd_x - lineStart_x) * (point_y - lineStart_y) - (lineEnd_y - lineStart_y) * (point_x - lineStart_x)) / DistanceTo(lineStart_x, lineStart_y, lineEnd_x, lineEnd_y)
If tI >= 0R AndAlso tI <= 1.0R Then
Return Math.Abs(dP)
Else
Return Math.Min(DistanceTo(point_x, point_y, lineStart_x, lineStart_y), DistanceTo(point_x, point_y, lineEnd_x, lineEnd_y))
End If
End Function
Private Shared Function ClosestPointToSegment(P_x As Double, p_y As Double, A_x As Double, a_y As Double, B_x As Double, b_y As Double) As Double()
Dim a_to_p As PointF = New PointF(), a_to_b As PointF = New PointF()
Dim rikthex As Double, rikthey As Double
Dim s1(1) As Double
Dim p1_v1_X As Double, p1_v1_y As Double, distanca1 As Double, distanca2 As Double
a_to_p.X = P_x - A_x
a_to_p.Y = p_y - a_y
a_to_b.X = B_x - A_x
a_to_b.Y = b_y - a_y
Dim atb2 As Single = a_to_b.X * a_to_b.X + a_to_b.Y * a_to_b.Y
Dim atp_dot_atb As Single = a_to_p.X * a_to_b.X + a_to_p.Y * a_to_b.Y
Dim t As Single = atp_dot_atb / atb2
rikthex = A_x + a_to_b.X * t
rikthey = a_y + a_to_b.Y * t
If A_x > B_x Then
If rikthex < A_x And rikthex > B_x Then 'pika duhet ne rregulll
If a_y > b_y Then
If rikthey < a_y And rikthey > b_y Then 'pika duhet ne rregulll
Else
distanca1 = DistanceTo(P_x, p_y, A_x, a_y)
distanca2 = DistanceTo(P_x, p_y, B_x, b_y)
If distanca1 < distanca2 Then
rikthex = A_x
rikthey = a_y
Else
rikthex = B_x
rikthey = b_y
End If
End If
Else
If rikthey > a_y And rikthey < b_y Then 'pika duhet ne rregulll
Else
distanca1 = DistanceTo(P_x, p_y, A_x, a_y)
distanca2 = DistanceTo(P_x, p_y, B_x, b_y)
If distanca1 < distanca2 Then
rikthex = A_x
rikthey = a_y
Else
rikthex = B_x
rikthey = b_y
End If
End If
End If
Else
distanca1 = DistanceTo(P_x, p_y, A_x, a_y)
distanca2 = DistanceTo(P_x, p_y, B_x, b_y)
If distanca1 < distanca2 Then
rikthex = A_x
rikthey = a_y
Else
rikthex = B_x
rikthey = b_y
End If
End If
Else
If rikthex > A_x And rikthex < B_x Then 'pika duhet ne rregulll
If a_y > b_y Then
If rikthey < a_y And rikthey > b_y Then 'pika duhet ne rregulll
Else
distanca1 = DistanceTo(P_x, p_y, A_x, a_y)
distanca2 = DistanceTo(P_x, p_y, B_x, b_y)
If distanca1 < distanca2 Then
rikthex = A_x
rikthey = a_y
Else
rikthex = B_x
rikthey = b_y
End If
End If
Else
If rikthey > a_y And rikthey < b_y Then 'pika duhet ne rregulll
Else
distanca1 = DistanceTo(P_x, p_y, A_x, a_y)
distanca2 = DistanceTo(P_x, p_y, B_x, b_y)
If distanca1 < distanca2 Then
rikthex = A_x
rikthey = a_y
Else
rikthex = B_x
rikthey = b_y
End If
End If
End If
Else
distanca1 = DistanceTo(P_x, p_y, A_x, a_y)
distanca2 = DistanceTo(P_x, p_y, B_x, b_y)
If distanca1 < distanca2 Then
rikthex = A_x
rikthey = a_y
Else
rikthex = B_x
rikthey = b_y
End If
End If
End If
s1(0) = rikthex
s1(1) = rikthey
Return s1
End Function
In case anybody looking for python implementation, here is the code:
p1 and p2 is line, p3 is the point
def p4(p1, p2, p3):
x1, y1 = p1
x2, y2 = p2
x3, y3 = p3
dx, dy = x2-x1, y2-y1
det = dx*dx + dy*dy
a = (dy*(y3-y1)+dx*(x3-x1))/det
x= x1+a*dx, y1+a*dy
# print(x)
if x[0]<x1 or x[1]<y1:
return p1
elif x[0]>x2 or x[1]>y2:
return p2
else:
return x
This was taken from another thread and modified a little. Python: point on a line closest to third point
The algorithm would be quite easy:
you have 3 points - triangle. From there you should be able to find AB, AC, BC.
Theck this out: http://www.topcoder.com/tc?d1=tutorials&d2=geometry1&module=Static#line_point_distance
