This is actually not so hard given the decription here:
http://mathworld.wolfram.com/Circle-CircleIntersection.html

A proposed algorithm:

- Find x - as described in the link.
- Calculate y.

Both should be done using any 2 circles.

- Plug the points (x,y) and (x,-y) in the 3 circle.
- The solution is either that all three circles intersect at:
x,y
x,-y
or not at all.

Another suggestion ...
I read again your question, and realized you're not looking to find
the point it self...

However, if you draw all 9 circles on a paper (the 3 intersecting, plus 2 smaller and larger for r+e and r-e, where e is error), you notice the following. Your intersection point lies within a polygon. You
can easily calculate the vertices of this polygon. And then your problem becomes either:
find a point in polygon.
Or you write an objection function that finds these vertices, and then
you minimize that area.

To see what I mean about the circles, run:

```
# excuse me for the ugly code ...
import pylab
pylab.axes()
cir = pylab.Circle((1,0), radius=1, alpha =.2, fc='b')
cir1 = pylab.Circle((1,0), radius=0.9, alpha =.2, fc='b')
cir2 = pylab.Circle((1,0), radius=1.1, alpha =.2, fc='b')
cir3 = pylab.Circle((-1,0), radius=1, alpha =.2, fc='b')
cir4 = pylab.Circle((-1,0), radius=0.9, alpha =.2, fc='b')
cir5 = pylab.Circle((-1,0), radius=1.1, alpha =.2, fc='b')
cir6 = pylab.Circle((0,-1), radius=0.9, alpha =.2, fc='b')
cir7 = pylab.Circle((0,-1), radius=1.1, alpha =.2, fc='b')
cir8 = pylab.Circle((0,-1), radius=1, alpha =.2, fc='b')
pylab.gca().add_patch(cir)
pylab.gca().add_patch(cir1)
pylab.gca().add_patch(cir2)
pylab.gca().add_patch(cir3)
pylab.gca().add_patch(cir4)
pylab.gca().add_patch(cir5)
pylab.gca().add_patch(cir6)
pylab.gca().add_patch(cir7)
pylab.gca().add_patch(cir8)
pylab.axis('scaled')
pylab.show()
```