Device, system and method for detecting a direction of gaze based on a magnetic field interaction

What is claimed is: 1. An ophthalmic system comprising: a magnetic field generator disposed within an enclosure of an ophthalmic device and configured to generate a magnetic field which extends beyond the ophthalmic device to interact with an auxiliary reference device external to the ophthalmic device; a sensor disposed within the enclosure and coupled to the magnetic field generator to measure a magnetic field interaction with the auxiliary reference device as a load on the magnetic field generator, wherein the sensor is further configured to generate a magnetic field signal based on the magnetic field interaction; and a controller disposed within the enclosure and coupled to the sensor, wherein the controller includes logic that when executed by the controller causes the ophthalmic system to perform operations including: monitoring the magnetic field signal; and correlating the magnetic field signal to at least one of a gazing direction of a user wearing the ophthalmic device or an optical power setting for the ophthalmic device. 2. The ophthalmic system of claim 1 , further comprising: an accommodation lens disposed within the enclosure, wherein the controller is coupled to the accommodation lens and includes further logic that when executed by the controller causes the ophthalmic system to perform further operations including: detecting, in real-time, changes in the magnetic field signal; and electrically manipulating the accommodation lens to automatically change the optical power of the ophthalmic device in response to detecting changes in the magnetic field signal. 3. The ophthalmic system of claim 2 , wherein the magnetic field generator comprises an electromagnet circuit including a conductor which extends around the accommodation lens. 4. The ophthalmic system of claim 1 , wherein the auxiliary reference device comprises a passive circuit that passively loads the magnetic field. 5. The ophthalmic system of claim 1 , wherein the auxiliary reference device is configured to be implanted under a surface of skin of the user. 6. The ophthalmic system of claim 1 , wherein the auxiliary reference device comprises an active circuit that is powered by the magnetic field from the ophthalmic device and presents a modulated load on the magnetic field. 7. The ophthalmic system of claim 1 , wherein the controller further comprises logic that when executed by the controller causes the controller to perform further operations comprising: modulating the magnetic field to induce the load on the magnetic field generator. 8. An ophthalmic system comprising: one or more magnetic sensors disposed within an enclosure of an ophthalmic device, the one or more magnetic sensors configured to measure magnetic field interactions with a plurality of auxiliary reference devices disposed external to the ophthalmic device, the one or more magnetic sensors further configured to generate magnetic field signals based on the magnetic field interactions; and a controller disposed within the enclosure and coupled to the magnetic sensors, wherein the controller includes logic that when executed by the controller causes the ophthalmic system to perform operations including: measuring, with the one or more magnetic sensors, the magnetic field interactions between the ophthalmic device and the auxiliary reference devices external to the ophthalmic device; generating, with the one or more magnetic sensors, the magnetic field signals based on the magnetic field interactions; and correlating a combination of the magnetic field signals from the plurality of auxiliary reference devices to at least one of a gazing direction or an optical power for the ophthalmic device. 9. The ophthalmic system of claim 8 , wherein measuring the magnetic field interactions includes: detecting a first magnetic field modulation signature of a first one of the auxiliary reference devices; and detecting a second magnetic field modulation signature of a second one of the auxiliary reference devices, wherein the first and second magnetic field modulations signatures enables the ophthalmic device to distinguish between the magnetic field interactions with the plurality of auxiliary reference devices for triangulation of a position or an orientation of the ophthalmic device relative to the plurality of auxiliary reference devices. 10. The ophthalmic system of claim 8 , wherein the enclosure includes: a concave surface; and a convex surface; wherein the concave surface is configured to be removably mounted over a cornea and the convex surface is configured to be compatible with eyelid motion when the concave surface is so mounted. 11. The ophthalmic system of claim 8 , wherein the ophthalmic device comprises an intraocular device. 12. The ophthalmic system of claim 8 , wherein the magnetic sensors comprise Hall effect sensors. 13. A method at an ophthalmic device, the method comprising: generating a first magnetic field with a magnetic field generator disposed in or on the ophthalmic device; measuring a first magnetic field interaction between the ophthalmic device and a first auxiliary reference device external to the ophthalmic device as a load imparted by the first auxiliary reference device onto the magnetic field generator via the first magnetic field, the first magnetic field interaction occurring while the first auxiliary reference device is adhered on or disposed under a surface of skin of a user; generating a first one or more magnetic field signals in response to the measuring the first magnetic field interaction; correlating the first one or more magnetic field signals to a gazing direction of an eye, wherein the ophthalmic device is mounted in or on the eye; and detecting, in real-time, changes in the gazing direction based upon changes in the first one or more magnetic field signals. 14. The method of claim 13 , further comprising: electrically manipulating an accommodation lens of the ophthalmic device to automatically change an optical power of the ophthalmic device in response to detecting changes in the gazing direction. 15. The method of claim 13 , wherein the first auxiliary reference device comprises a passive circuit that passively loads the first magnetic field, the first auxiliary reference device positioned peripherally to an eye which includes the cornea. 16. The method of claim 13 , wherein the magnetic field generator comprises an electromagnet circuit of the ophthalmic device. 17. The method of claim 16 , further comprising: modulating the first magnetic field to induce the load on the electromagnet circuit. 18. The method of claim 16 , wherein the generating the first magnetic field includes powering a modulation of the first magnetic field by the first auxiliary reference device. 19. The method of claim 14 , further comprising: measuring a second magnetic field interaction between the ophthalmic device and a second auxiliary reference device external to the ophthalmic device; and generating a second one or more magnetic field signals based on the second magnetic field interaction, wherein correlating the first one or more magnetic field signals to the gazing direction includes correlating a combination of the first one or more magnetic field signals and the second one or more magnetic field signals to the gazing direction. 20. The method of claim 19 , wherein measuring the first magnetic field interaction includes detecting a first magnetic field modulation signature of the first auxiliary reference device