# 3D trilateration Java

I have a problem with my App in Java. I have 3 points and 3 distance on the Earth and I need to find 4th point. In my code I used some equeals from wikipedia to count trilateration with that. The solution should be : 49.195167,16.607208 (GPS on GoogleMap).

I would be very glad, if somebody can help to find mistakes in code. Because it counts wrong GPS.

Thank you a lot!

``````    float earthR = 6371;
float p1x = (float) 61.47;
float p1y = (float) 23.76;
float p2x = (float) 42.80;
float p2y = (float) -1.63;
float p3x= (float) 39.67;
float p3y= (float) 20.85;
float r1 = 1470;
float r2 = 1617;
float r3 = 1127;

float exx = (float) ((P2x-P1x)/Math.sqrt(Math.pow(P2z-P1z, 2)+Math.pow((P2x-P1x),2)+Math.pow((P2y-P1y),2)));
float exy = (float) ((P2y-P1y)/Math.sqrt(Math.pow(P2z-P1z, 2)+Math.pow((P2x-P1x),2)+Math.pow((P2y-P1y),2)));
float exz = (float) ((P2z-P1z)/Math.sqrt(Math.pow(P2z-P1z, 2)+Math.pow((P2x-P1x),2)+Math.pow((P2y-P1y),2)));
float EX = (float) Math.sqrt(Math.pow(exx, 2)+Math.pow(exy, 2)+Math.pow(exz,2));

float i = (float) Math.sqrt(Math.pow((P3x-P1x)*EX, 2)+Math.pow((P3y-P1y)*EX, 2)+Math.pow((P3z-P1z)*EX, 2));

float eyx = (float) ((P3x-P1x-(i*exx))/Math.sqrt((Math.pow(P3z-P1z-(i*exz),2))+(Math.pow(P3x-P1x-(i*exx),2))+(Math.pow(P3y-P1y-(i*exy),2))));
float eyy = (float) ((P3y-P1y-(i*exy))/Math.sqrt((Math.pow(P3z-P1z-(i*exz),2))+(Math.pow(P3x-P1x-(i*exx),2))+(Math.pow(P3y-P1y-(i*exy),2))));
float eyz = (float) ((P3z-P1z-(i*exz))/Math.sqrt((Math.pow(P3z-P1z-(i*exz),2))+(Math.pow(P3x-P1x-(i*exx),2))+(Math.pow(P3y-P1y-(i*exy),2))));
float EY = (float) Math.sqrt(Math.pow(eyx, 2)+Math.pow(eyy, 2)+Math.pow(eyz, 2));

float ezx = (exy*eyz)-(exz*exy);
float ezy = (exz*eyx)-(exx*eyz);
float ezz = (exx*eyy)-(exy*eyx);
float EZ = (float) Math.sqrt(Math.pow(ezx, 2)+Math.pow(ezy, 2)+Math.pow(ezz, 2));

float d = (float) Math.sqrt((Math.pow(P2x-P1x,2))+(Math.pow(P2y-P1y,2))+Math.pow(P2z-P1z, 2));

float j = (float) Math.sqrt(Math.pow((P3x-P1x)*EY, 2)+Math.pow((P3y-P1y)*EY, 2)+Math.pow((P3z-P1z)*EY, 2));
float x = (float) ((Math.pow(r1, 2)-Math.pow(r2, 2)+Math.pow(d, 2))/(2*d));
float y = (float) (Math.pow(r1, 2)-Math.pow(r3, 2)+Math.pow(i, 2)+Math.pow(j, 2))/(2*j)- (i*x/j);

float z1 = (float) (Math.pow(r1,2) - Math.pow(x,2) - Math.pow(y,2));
if (z1<0){ z1 = z1*(-1);}
float z = (float) Math.sqrt(z1);

float lat = (float) Math.toDegrees(Math.atan2(y,x));
float lon = (float) Math.toDegrees(Math.asin((z)/earthR));
System.out.println(lat);
System.out.println(lon);
``````
-

First, if `z1` is less than zero, that means there is no solution. You can think it as three spheres no intersecting.

``````if(z1 < 0) return NO_SOLUTION;
``````

If it is greater than zero, that means you have two intersections.

``````if(z1 > 0)
{
z1 = Math.sqrt(z1);
z2 = z1*-1;
}
``````

After this step, you have 2 points, which are:

``````result1 = P1 + exx + eyy + ez*z1;
result2 = P1 + exx + eyy + ez*z2;
``````

This is where third point comes into play. You calculate the distance of those two results to `P3`.

``````if(Math.abs(distance(result1, P3) - r3) < Math.abs(distance(result2, P3) - r3))
return result1;
else return result2;
``````

which means, you pick the point which satisfies the distance from it to `P3` i.e. `r3`.

-