Rotationally stabilized contact lens with improved comfort and method of optimization

What is claimed is: 1. A method that optimizes the stabilization of a contact lens on eye while maximizing comfort comprising the steps of: defining a matrixed set of peripheral geometries having a noncircularity component and a thickness differential wherein the noncircularity component defined as the ratio of the largest inscribed diameter divided by the smallest circumscribed diameter wherein said ratio ranges from 95% to 60% from a true circle and the thickness differential defined as the additive thickness to the nominal thickness of the nominal thin portions of the lens which ranges from 0.1 mm to 0.4 mm wherein the matrixed set includes a minimum of two noncircularity values and a minimum of two thickness differential values, calculating a time for the lens to stabilize on eye for a given noncircularity component and a given thickness differential; creating a contour plot showing the time to stabilize for each item in the matrixed set; assessing the contour plot and defining a preferred region based upon at least one of three variables wherein the variables include maximizing comfort which is a function of lens thickness, minimizing time to stabilize, and minimizing manufacturing difficulty which is a function of noncircularity; selecting the peripheral geometry with a noncircularity component and a thickness differential which produces a time to stabilize within the preferred region; and fabricating a contact lens having a selected noncircularity component and a corresponding selected thickness differential. 2. The method of claim 1 wherein the maximizing comfort variable is inversely proportional to the thickness differential. 3. The method of claim 1 wherein the minimizing manufacturing difficulty variable is inversely proportional to the extent of noncircularity. 4. The method of claim 1 wherein the minimizing time to stabilize variable is a function of both the thickness differential and the extent of noncircularity. 5. The method of claim 1 wherein the matrixed set of peripheral geometries is derived from an initial starting design selected from the group consisting of known, existing, and commercialized designs.