Least distance from a point to an area

I am trying to find a point (P2) in a closed area that has the minimum distance to a point (P1). The area is built of homogenous pixels, it is not shaped perfectly and it is not necessarily convex. This is basically a problem of reaching an area from the shortest path.

The whole space is a stored in the form of a bitmap in the memory. What is the best method to find P2? Should I go with random search (optimization) methods? Optimization methods do not give the exact minimum but they are faster than brute forcing every pixel of the area. I need to perform thousands of these decisions in a few seconds.

The MinX,MinY,MaxX,MaxY of the area is available.

Thanks.

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Is the shape convex? otherwise solution might not be unique. You could find some answers here: math.stackexchange.com/questions/170731/… –  Maxx Mar 21 '13 at 13:31
If you could also explain the implementation requirement of this logic, a feasible solution can be thought of. –  Murtuza Kabul Mar 21 '13 at 13:33
How are the points in the area stored? Do we have fast access to the boundary points (the only ones that are relevant)? –  chepner Mar 21 '13 at 13:40
May we assume the area is convex? –  Ivaylo Strandjev Mar 21 '13 at 13:45
@chepner I added the information. The whole space is stored in a memory bitmap. –  wmac Mar 21 '13 at 13:45

Here is my code, it's a discrete version using discrete coordinates:

Hint: the method I used to find the circumference of the Area is simple, it's like how do you know the beach from the land ? answer: the beach is covered by Sea from one side, so in my graph matrix, NULL reference is Sea, Points are Land!

Class Point:

``````class Point
{
public int x;
public int y;

public Point (int X, int Y)
{
this.x = X;
this.y = Y;
}
}
``````

Class Area:

``````class Area
{
public ArrayList<Point> points;

public Area ()
{
p = new ArrayList<Point>();
}
}
``````

Discrete Distance Utility Class:

``````class DiscreteDistance
{

public static int distance (Point a, Point b)
{
return Math.sqrt(Math.pow(b.x - a.x,2), Math.pow(b.y - a.y,2))
}

public static int distance (Point a, Area area)
{
ArrayList<Point> cir = circumference(area);
int d = null;

for (Point b : cir)
{
if (d == null || distance(a,b) < d)
{
d = distance(a,b);
}
}

return d;
}

ArrayList<Point> circumference (Area area)
{
int minX = 0;
int minY = 0;
int maxX = 0;
int maxY = 0;

for (Point p : area.points)
{
if (p.x < minX) minX = p.x;
if (p.x > maxX) maxX = p.x;
if (p.y < minY) minY = p.y;
if (p.y > maxY) maxY = p.y;
}

int w = maxX - minX +1;
int h = maxY - minY +1;

Point[][] graph = new Point[w][h];

for (Point p : area.points)
{
graph[p.x - minX][p.y - minY] = p;
}

ArrayList<Point> cir = new ArrayList<Point>();

for (int i=0; i<w; i++)
{
for (int j=0; j<h; j++)
{
if ((i > 0 && graph[i-1][j] == null)
|| (i < (w-1) && graph[i+1][j] == null)
|| (j > 0 && graph[i][j-1] == null)
|| (i < (h-1) && graph[i][j+1] == null))
{
}
}
}

return cir;
}
}
``````
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Khaled, Thanks. I guess I need to have the edges in the Area ArrayList, right? And the area should be a polygon? –  wmac Mar 21 '13 at 14:03
First, to thank me up-vote my solution .. basically, I'm doing a linear minimization over distance(point, circumference) .. if you want to find minimal distance between two areas, you simply have to do linear minimization over distance(circumferenceA, circumferenceB) –  Khaled A Khunaifer Mar 21 '13 at 14:07
So what does the "ArrayList<Point> points" in the Area class contain? –  wmac Mar 21 '13 at 14:10
that should've been obvious, An area is made of points .. check back the figure you provided in your post, it says "Area (set of pixels)", basically here we use Point instead of Pixel –  Khaled A Khunaifer Mar 21 '13 at 14:14
If you're going to loop over each point in the area at least three times, why not just calculate the distance to each one once and record the min? Taking the square root and squaring are not so costly compared to what you are doing to make it worthwhile. –  jerry Mar 21 '13 at 14:44

We have to assume you know or can easily find at least one pixel address (x0,y0) inside the area. The fastest solution will certainly be to search from this pixel in a straight line, say in the plus x direction Alternately, since you have a bounding box, pick the compass point toward the nearest boundary and go in that direction.

When you find the edge of the region, search depth first along the boundary. For general polygons with self-intersections and/or holes, this will have to be a complete and carefully implemented DFS maintaining a set of already-visited vertices. Only if the polygon is simple will it suffice to remember only the last-visited pixel to avoid doubling back over what's already searched.

During the DFS, compute the distance squared to p1 for each boundary pixel and track the minimum.

Note, if you are really pressed for performance this distance squared can be updated incrementally to replace multiplications with additions. I.e. if you know `d2=(x2-x1)^2+(y2-y1)^2` and then increment `x2` by 1 to take the next step around the boundary, the new squared distance is

``````((x2+1) - x1)^2 + (y2-y1)^2 = d2 + 2(x2 - x1) + 1
``````

So you can update `d2` with `d2 += 2(x2 - x1) + 1`. The multiplication by 2 is of course just a left shift, so this is very cheap. There are similar very cheap updates for steps in each direction.

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