Wearable inductive-force sensor

What is claimed is: 1. A force sensor comprising: a substrate; a first, second and third coil disposed on said substrate each adapted to generate an initial magnetic field upon receipt of an A.C. (alternating current) signal; a capacitor coupled in parallel with each one of said coils; an electrically conductive section supported by a section of flexible material, wherein said flexible material is attached to said substrate, such that said electrically conductive section is spaced from said coils, whereby one of said initial magnetic fields forms one or more corresponding induced magnetic fields in said electrically conductive section; wherein upon an application of a force to the sensor, at least one of said substrate and said electrically conductive section moves, such that a position of one or more said coils relative to said electrically conductive section is changed, whereby one or more of said induced magnetic fields are detected by one or more of said coils, so as to change a magnitude of inductance of one or more of said coils, with each said change in magnitude of inductance being associated with a measurement of the application of force; and wherein said electrically conductive section has an edge that passes through a center of said first and second coils. 2. The force sensor of claim 1 , further comprising an insole of a shoe that includes said coils. 3. The force sensor of claim 1 , wherein said substrate comprises a dielectric material. 4. The force sensor of claim 1 , wherein said coils comprise spiral-wound coils. 5. The force sensor of claim 4 , wherein said spiral-wound coils comprise planar coils. 6. The force sensor of claim 5 , wherein said spiral-wound planar coils comprise a plurality of turns. 7. The force sensor of claim 1 , wherein said section of flexible material is formed of rubber. 8. The force sensor of claim 1 , wherein said electrically conductive section comprises stainless steel. 9. The force sensor of claim 1 , further comprising: a force-measurement device coupled to said first, second and third coils, wherein said force-measurement device is configured to measure an amount of movement of said electrically conductive section relative to said coils, so as to calculate therefrom the measurement of the application of the force. 10. The force sensor of claim 9 , wherein said force-measurement device comprises: a resistor coupled in series with said first, second and third coils; an A.C. (alternating current) signal generator that is coupled in series with said resistor; and a data acquisition unit coupled in parallel with said first, second and third coils; wherein said A.C. signal generator generates a combined signal, which includes a plurality of signals each having a resonant frequency associated with said first, second and third coils respectively, such that said data acquisition unit monitors said first, second and third coils to identify the amount of force applied to the sensor. 11. The force sensor of claim 9 , wherein said force-measurement device includes a communication interface to transfer the calculated amount of force to a remote computer. 12. The force sensor of claim 9 , wherein said force-measurement device calculates the amount of force in real-time. 13. The force sensor of claim 1 , further comprising: a controller configured to identify the change in magnitude of said magnetic field of one or more of said coils to generate therefrom a measurement of one or more forces applied to the sensor. 14. The force sensor of claim 1 , wherein said electrically conductive section covers said third coil. 15. The force sensor of claim 1 , wherein said substrate comprises an insole. 16. The force sensor comprising: a substrate; a first, second and third coil disposed on said substrate each adapted to generate an initial magnetic field upon receipt of an A.C. (alternating current) signal; a capacitor coupled in parallel with each one of said coils; an electrically conductive section supported by a section of flexible material, wherein said flexible material is attached to said substrate, such that said electrically conductive section is spaced from said coils, whereby one of said initial magnetic fields forms one or more corresponding induced magnetic fields in said electrically conductive section, and wherein said section of flexible material comprises a plurality of individual sections of flexible material; and a cover plate that is supported by said plurality of individual sections of flexible material, with said electrically conductive section being attached to said cover plate, wherein upon an application of a force to the sensor, at least one of said substrate and said electrically conductive section moves, such that a position of one or more said coils relative to said electrically conductive section is changed, whereby one or more of said induced magnetic fields are detected by one or more of said coils, so as to change a magnitude of inductance of one or more of said coils, with each said change in magnitude of inductance being associated with a measurement of the application of force.