To determine the 3D location of the object I would suggest ray tracing.

Assuming the model is in worldspace coordinates you'll also need to know the worldspace coordinates of the eye location and the worldspace coordinates of the image plane. Using those two points you can calculate a ray which you will use to intersect with the model, which I assume consists of triangles.

Then you can use the ray triangle test to determine the 3D location of the touch, by finding the triangle that has the closest intersection to the image plane. If you want which triangle is touched you will also want to save that information when you do the intersection tests.

This page gives an example of how to do ray triangle intersection tests: http://www.scratchapixel.com/lessons/3d-basic-lessons/lesson-9-ray-triangle-intersection/ray-triangle-intersection-geometric-solution/

**Edit:**

Updated to have some sample code. Its some slightly modified code I took from a C++ raytracing project I did a while ago so you'll need to modify it a bit to get it working for iOS. Also the code in its current form wouldn't even be useful since it doesn't return the actual intersection point but rather if the ray intersects the triangle or not.

```
// d is the direction the ray is heading in
// o is the origin of the ray
// verts is the 3 vertices of the triangle
// faceNorm is the normal of the triangle surface
bool
Triangle::intersect(Vector3 d, Vector3 o, Vector3* verts, Vector3 faceNorm)
{
// Check for line parallel to plane
float r_dot_n = (dot(d, faceNorm));
// If r_dot_n == 0, then the line and plane are parallel, but we need to
// do the range check due to floating point precision
if (r_dot_n > -0.001f && r_dot_n < 0.001f)
return false;
// Then we calculate the distance of the ray origin to the triangle plane
float t = ( dot(faceNorm, (verts[0] - o)) / r_dot_n);
if (t < 0.0)
return false;
// We can now calculate the barycentric coords of the intersection
Vector3 ba_ca = cross(verts[1]-verts[0], verts[2]-verts[0]);
float denom = dot(-d, ba_ca);
dist_out = dot(o-verts[0], ba_ca) / denom;
float b = dot(-d, cross(r.o-verts[0], verts[2]-verts[0])) / denom;
float c = dot(-d, cross(verts[1]-verts[0], o-verts[0])) / denom;
// Check if in tri or if b & c have NaN values
if ( b < 0 || c < 0 || b+c > 1 || b != b || c != c)
return false;
// Use barycentric coordinates to calculate the intersection point
Vector3 P = (1.f-b-c)*verts[0] + b*verts[1] + c*verts[2];
return true;
}
```

The actual intersection point you would be interested in is P.