Enhanced coupler performance winding approach

The invention claimed is: 1. An apparatus comprising: a carrier substrate; a binocular ferrite core attached to a top surface of said carrier substrate by an adhesive material disposed along a first vertical side of said binocular ferrite core and a second vertical side of said binocular ferrite core, wherein (i) a space is formed between a bottom side surface of said binocular ferrite core, said adhesive material disposed along said first vertical side surface of said binocular ferrite core, said adhesive material disposed along said second side surface of said binocular ferrite core, and said top surface of said carrier substrate, (ii) said adhesive material does not encroach on said space between said binocular core and said carrier substrate and adds tune position security, and (iii) said binocular ferrite core has a first hole and a second hole running parallel to said top surface of said carrier substrate; a first set of wire windings passing through said binocular ferrite core parallel to said top surface of said carrier substrate and between said bottom side surface of said binocular ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached; a second set of wire windings passing through said binocular ferrite core parallel to said top surface of said carrier substrate and between said bottom side surface of said binocular ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached; a third set of wire windings passing through said binocular ferrite core parallel to said top surface of said carrier substrate and between said bottom side surface of said binocular ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached; and a fourth set of wire windings passing through said binocular ferrite core parallel to said top surface of said carrier substrate and between said bottom side surface of said binocular ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached. 2. The apparatus according to claim 1 , wherein: said first set of wire windings and said second set of wire windings pass through said first hole in said binocular ferrite core; and said third set of wire windings and said fourth set of wire windings pass through said second hole in said binocular ferrite core. 3. The apparatus according to claim 1 , wherein at least one of the wire windings is formed with a wire gauge larger than a wire gauge of another of the wire windings. 4. The apparatus according to claim 3 , wherein said wire winding formed with the larger gauge wire is a primary winding of the apparatus. 5. The apparatus according to claim 1 , wherein said binocular ferrite core comprises a plurality of binocular sections arranged one adjacent to the other along each axis of said first and second holes to form a longer core. 6. The apparatus according to claim 5 , wherein the plurality of binocular sections of said binocular ferrite core are epoxied together. 7. The apparatus according to claim 1 , wherein said binocular ferrite core is attached to said top surface of said carrier substrate by epoxy disposed along each of said first vertical side and said second vertical side of said binocular ferrite core. 8. The apparatus according to claim 1 , wherein said binocular ferrite core is attached to said top surface of said carrier substrate by epoxy disposed over a top surface and down each vertical side of said binocular ferrite core. 9. The apparatus according to claim 1 , wherein said wire windings passing between said bottom side surface of said binocular ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached are pressed together. 10. The apparatus according to claim 1 , wherein a space between one or more wire windings passing between said bottom side surface of said binocular ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached are adjusted to obtain a selected performance. 11. The apparatus according to claim 1 , wherein said binocular ferrite core and said wire windings form a radio frequency (RF) directional coupler. 12. The apparatus according to claim 1 , wherein said carrier substrate contains a ground plane. 13. The apparatus according to claim 1 , wherein said binocular ferrite core comprises one or more of Manganese-Zinc Ferrite, Nickel-Zinc Ferrite, Carbonyl, Phenolic, and Polyamide. 14. A method of constructing a radio frequency (RF) coupler comprising the steps of: winding a first set of wire windings on a binocular ferrite core, wherein said first set of wire windings passes through said binocular ferrite core parallel to a top surface of a carrier substrate and between a bottom side surface of said binocular ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached; winding a second set of wire windings on said binocular ferrite core, wherein said second set of wire windings passes through said binocular ferrite core parallel to said top surface of said carrier substrate and between said bottom side surface of said ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached; winding a third set of wire windings on said binocular ferrite core, wherein said third set of wire windings passes through said binocular ferrite core parallel to said top surface of said carrier substrate and between said bottom side surface of said ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached; and winding a fourth set of wire windings on said binocular ferrite core, wherein said fourth set of wire windings passes through said binocular ferrite core parallel to said top surface of said carrier substrate and between said bottom side surface of said ferrite core and said top surface of said carrier substrate to which said binocular ferrite core is attached, wherein said first, second, third, and fourth sets of wire windings are enclosed in a space bounded by said bottom side surface of said ferrite core, said top surface of said carrier substrate, and an adhesive material on each vertical side surface of said binocular ferrite core, said adhesive material attaching said binocular ferrite core to said top surface of said carrier substrate and adding tune position security. 15. The method according to claim 14 , wherein said first set of wire windings and said second set of wire windings pass through said first hole in said binocular ferrite core and said third set of wire windings and said fourth set of wire windings pass through said second hole in said binocular ferrite core. 16. The method according to claim 14 , wherein said material attaching said binocular ferrite core to said top surface of said carrier substrate comprises epoxy. 17. The method according to claim 16 , wherein the epoxy completely encompasses the binocular ferrite core from one side, over the top of the core to the other side. 18. The method according to claim 14 , further comprising the step of: adjusting one or more sets of wire windings to tune a performance parameter of the RF coupler. 19. The method according to claim 18 , wherein adjusting the one or more sets of wire windings comprises crossing a pair of windings in at least one of the four sets of wire windings. 20. The method according to claim 18 , wher