second shot

**subsolution:** (analytic geometry basics, skip if you are familiar with this) finding point of the opposite half-plane

Example: Let's have two points: **A**=[a,b]=[2,3] and **B**=[c,d]=[4,1]. Find vector **u** = A-B = (2-4,3-1) = (-2,2). This vector is parallel to **AB** line, so is the vector (-1,1). The equation for this line is defined by vector **u** and point in **AB** (i.e. **A**):

```
X = 2 -1*t
Y = 3 +1*t
```

Where **t** is any real number. Get rid of **t**:

```
t = 2 - X
Y = 3 + t = 3 + (2 - X) = 5 - X
X + Y - 5 = 0
```

Any point that fits in this equation is in the line.

Now let's have another point to define the half-plane, i.e. **C**=[1,1], we get:

```
X + Y - 5 = 1 + 1 - 5 < 0
```

Any point with opposite non-equation sign is in another half-plane, which are these points:

```
X + Y - 5 > 0
```

**solution:** finding the minimum triangle that fits the point **S**

- Find the closest point
**P** as min(sqrt( (**Xp** - **Xs**)^2 + (**Yp** - **Ys**)^2 ))
- Find perpendicular vector to
**SP** as **u** = (-Yp+Ys,Xp-Xs)
- Find two closest points
**A**, **B** from the opposite half-plane to **sigma** = **pP** where **p** = **Su** (see subsolution), such as **A** is on the different site of line **q** = **SP** (see final part of the subsolution)
- Now we have triangle
**ABP** that covers **S**: calculate sum of distances |**SP**|+|**SA**|+|**SB**|
- Find the second closest point to
**S** and continue from 1. If the sum of distances is smaller than that in previous steps, remember it. Stop if **|SP|** is greater than the smallest sum of distances or no more points are available.

I hope this diagram makes it clear.