To adjust the FOV to fit the sphere, I needed to use inverse trigonometric functions to calculate the angle from the triangle formed from the distance to the sphere and the furthest visible point on the sphere.
Image of the triangle that will give the correct angle
// to get the fov to fit the sphere into the camera
var vFOV = 2 * Math.asin(sphereRadius / distance);
// get the project's aspect ratio to calculate a horizontal fov
var aspect = this.width / this.height;
// more trig to calculate a horizontal fov, used to fit a sphere horizontally
var hFOV = 2 * Math.atan(Math.tan(vFOV / 2) / aspect);
This will give the answer in radians. Multiply the hFOV or vFOV to degrees
fov * (180 / Math.PI) and apply to
I initially ran into the trap of using the wrong triangle. As this answer states
"The sphere is being clipped for the same reason that if you stand close to a large sphere you can't see its "north pole"
Dont do this:
Image of the wrong triangle for a cropped view