If you have 3 positions in your collection, and if the radius of the circle of positions isn't too great (less than 50km or so) then you won't go far wrong using the formula for computing a
circle from 3 points (Google that) and pretending that the lat/long coordinates on the (approximately) spherical Earth are y/x coordinates on the Cartesian plane.
If you have more than 3 positions then you have too many for a circle -- the problem is not that you can't compute the circle from (say) 8 positions, but that you can compute
8-choose-3==56 circles and they are very unlikely to coincide. In this case you could do some sort of averaging to figure out one circle to bind them all.
As the radius of the circle you are looking for gets larger (I'm being deliberately vague here) then the plane approximation to the surface of the Earth gets worse and approximating an elliptical geometry by plane geometry becomes increasingly inadequate. On the surface of a sphere, for example, any 2 points define a circle (the great circle that goes through both points) unless they are antipodal in which case they define an infinity of circles. Now you need to be a lot cleverer ...