Induction heating coils with uniform heating

What is claimed is: 1. An induction heating system comprising: a ferromagnetic susceptor mounted proximate an exterior of flight surface of an aircraft; at least one electrically conductive spiral pancake coil mounted proximate the ferromagnetic susceptor, said at least one electrically conductive spiral pancake coil powered by a first AC power source with a first frequency; and, at least one compensating coil mounted proximate the ferromagnetic susceptor overlaying the at least one electrically conductive spiral pancake coil and having a geometry determined to provide substantially net-zero flux with respect to the at least one electrically conductive spiral pancake coil and positioned to induce induction heating with a portion of the at least one compensating coil aligned over a line segment in the middle of the at least one spiral pancake coil where a field minimum occurs, thereby eliminating a cold spot at the field minimum, said at least one compensating coil powered by a second AC power source with a second frequency adapted to induce average heating by the at least one compensating coil additive to average heating induced by the at least one electrically conductive spiral pancake coil. 2. The induction heating system as defined in claim 1 wherein the at least one electrically conductive spiral pancake coil comprises a first plurality of electrically conductive spiral pancake coils. 3. The induction heating system as defined in claim 2 wherein the at least one compensating coil comprises a second plurality of electrically conductive compensating coils. 4. The induction heating system as defined in claim 2 wherein the first plurality of electrically conductive spiral pancake coils comprises a pair of spiral pancake coils. 5. The induction heating system as defined in claim 4 wherein the pair of spiral pancake coils are symmetric about a nose line and the at least one compensating coil comprises a third coil mounted on top of the spiral pancake coil pair symmetric about the nose line. 6. The induction heating system as defined in claim 2 wherein the at least one compensating coil comprises a second plurality of electrically conductive coils. 7. The induction heating system as defined in claim 6 wherein the first plurality of electrically conductive spiral pancake coils comprises a pair of spiral pancake coils. 8. The induction heating system as defined in claim 7 wherein the pair of spiral pancake coils are symmetric about a nose line and the second plurality of electrically conductive compensating coils comprises a second coil pair mounted on top of the spiral pancake coil pair symmetric about the nose line. 9. The induction heating system as defined in claim 1 wherein the second AC power source comprises a phase adjustment component in series with the at least one compensating coil and connected to the first AC power supply that varies current phase of a third coil randomly in time. 10. The induction heating system as defined in claim 9 wherein the phase adjustment component is selected from a set of a solenoid, a capacitor, or a combination thereof. 11. An induction heating system comprising: a ferromagnetic susceptor mounted proximate an exterior of flight surface of an aircraft; a plurality of segmented solenoids mounted proximate the ferromagnetic susceptor, said plurality of segmented solenoids powered by a first AC power source with a first frequency; and, at least one compensating coil mounted proximate the ferromagnetic susceptor overlaying the plurality of segmented solenoids and having a geometry determined to provide substantially net-zero flux with respect to the plurality of segmented solenoids and positioned to induce induction heating with a portion of the at least one compensating coil providing a coil loop intermediate each adjacent pair of solenoids and providing tangential magnetic flux at the cold spots of the segmented solenoids, said at least one compensating coil powered by a second AC power source with a second frequency adapted to induce average heating by the at least one compensating coil additive to average heating induced by at least one of the plurality of segmented solenoids. 12. The induction heating system as defined in claim 11 wherein the at least one compensating coil comprises a meander coil mounted to provide a coil loop intermediate each adjacent pair of solenoids. 13. A method to provide uniform induction heating for deicing and anti-icing flight surfaces on an aircraft, comprising: providing a ferromagnetic susceptor sheet mounted proximate an exterior of flight surfaces of an aircraft; mounting at least one electrically conductive spiral pancake coil proximate the ferromagnetic susceptor to inductively heat the ferromagnetic susceptor, said at least one electrically conductive spiral pancake coil powered by a first AC power source with a first frequency; and mounting at least one compensating coil proximate the ferromagnetic susceptor overlaying the at least one electrically conductive coil and having a geometry determined to provide substantially net-zero flux with respect to the at least one electrically conductive coil and positioned to induce induction heating with a portion of the at least one compensating coil aligned over a line segment in the middle of the at least one spiral pancake coil where a field minimum occurs, thereby eliminating a cold spot at the field minimum, said one compensating coil powered by a second AC power source with a second frequency adapted to induce average heating by the at least one compensating coil additive to average heating induced by the at least one electrically conductive spiral pancake coil. 14. The method as defined in claim 13 wherein the at least one compensating coil comprises a plurality of electrically conductive coils. 15. The method as defined in claim 13 wherein the flight surfaces of the aircraft comprise a leading edge of the wing or engine cowling. 16. The method as defined in claim 13 wherein the second AC power source comprises an electronic circuit in series with the at least one compensating coil, said electronic circuit comprising a solenoid, a capacitor, or a combination thereof connected to the first AC power source and providing a current phase variation in the second plurality of electrically conductive coils in comparison to the current phase in the first plurality of electrically conductive coils. 17. The method as defined in claim 14 wherein the first plurality of electrically conductive spiral pancake coils and the second plurality of electrically conductive coils are positioned such that a predetermined non-uniform induced heat intensity pattern is accomplished on the susceptor sheet to accommodate variation in a heat transfer rate pattern from the susceptor sheet to an adjacent ambient resulting from a shape geometry induced air flow pattern on the flight surfaces. 18. The method as defined in claim 14 further comprising controlling a ratio of currents in the first plurality of electrically conductive spiral pancake coils versus the second plurality of electrically conductive coils to affect uniformity of heating by the first plurality of electrically conductive spiral pancake coils and the second plurality of electrically conductive coils. 19. The method as defined in claim 18 wherein the step of controlling the ratio of currents is accomplished with a microprocessor controller associated with at least one of the power sources. 20. The induction heating system as defined in claim 12 wherein the segmented