High bandwidth current sensor and method therefor

What is claimed is: 1. A current sensor comprising, a current carrying trace located within a first metal layer of the substrate; and a first sensing trace located within a second metal layer of the substrate proximate to the current carrying trace; a second sensing trace located within a third metal layer of the substrate proximate to the current carrying trace, wherein the first metal layer is between the second metal layer and the third metal layer, the first sensing trace is looped in the same direction as the first sensing trace, and a first end of the first sensing trace is connected to a first end of the second sensing trace with a via between the second and third metal layers of the substrate; a sensing circuit, coupled to a second end of the first sensing trace and a second end of the second sensing trace, the sensing circuit configured to detect an electromagnetic force (emf) generated by magnetic flux inductively coupled from the current carrying trace to the first and second sensing traces. 2. The current sensor of claim 1 , wherein the current flowing within the current carrying trace is an alternating current. 3. The current sensor of claim 2 , wherein the alternating current is a pulsed alternating current. 4. The current sensor of claim 1 , wherein the current carrying trace and the first and second sensing traces are formed of copper. 5. The current sensor of claim 1 , wherein the detected emf represents a voltage difference between respective first ends of the first and second sensing traces, generated by a magnetic flux flowing through a surface of the sensing trace. 6. The current sensor of claim 1 , wherein at least one of the first and second sensing traces and current carrying trace is proximate to a surface or located on the surface of the substrate. 7. The current sensor of claim 1 , wherein the current sensor comprises a first and second substrate. 8. The current sensor of claim 7 , wherein the first substrate comprises of silicon and the second substrate comprises silicon dioxide. 9. The current sensor of claim 8 , wherein the second substrate comprises any insulation material compatible with CMOS processing. 10. The current sensor of claim 9 , wherein the current sensor is located substantially within the second substrate. 11. The current sensor of claim 1 , wherein the first and second sensing traces each forms an approximation of a loop. 12. The current sensor of claim 1 , wherein the emf detected by the previous and further sensing traces is added together. 13. The current sensor of claim 1 , wherein the previous and further sensing traces form a substantially three dimensional loop within the substrate. 14. A method of detecting current within a substrate comprising: detecting an electromagnetic force (emf) generated by magnetic flux inductively coupled from a current carrying trace to a first sensor trace and a second sensor trace located within the substrate, wherein the first sensor trace is contained within a first metal layer of the substrate, the second sensor trace is contained with a second metal layer of the substrate and the current carrying trace is contained with a third metal layer of the substrate, wherein the third metal layer is between the first and second metal layers; and transmitting the emf to a sensing device.