System and method of improving linearity of current sensor for a circuit interrupter

What is claimed is: 1. A circuit interrupter structured to electrically connect between a power source coupled to a hot conductor and a load, the circuit interrupter comprising: (a) separable contacts; (b) an operating mechanism coupled to the separable contacts; (c) an electronic trip unit coupled to the operating mechanism; and (d) a current sensor assembly comprising: (i) a harvester circuit comprising a harvester core, a primary conductor through which input current from the power source flows, and a secondary winding wound around a first part of the harvester core, the harvester circuit structured to harvest power from the power source and supply power to at least the operating mechanism and the electronic trip unit, wherein the harvester core saturates at a first input current level of a range of input current levels; (ii) a Rogowski coil comprising a toroid through the center of which the primary conductor passes, the Rogowski coil structured to measure voltage at an output of the Rogowski coil, the measured voltage indicative of output current of Rogowski coil, wherein linearity of the output of Rogowski coil to the input current deviates more than a deviation tolerance based at least in part on saturation of the harvester core at the first input current level, and (iii) a compensation coil wound around a second part of the harvester core, the compensation coil structured to delay saturation of the harvester core until the input current reaches a second input current level higher than the first input current level, wherein the electronic trip unit is structured to receive a signal including the measured voltage from the Rogowski coil, and cause the operating mechanism to open the separable contacts and interrupt current flowing through the circuit interrupter based at least in part on the measured voltage. 2. The circuit interrupter of claim 1 , wherein the compensation coil is arranged 180 degree opposite to the secondary winding of the harvester circuit. 3. The circuit interrupter of claim 2 , wherein in delaying the saturation of the harvester core, the compensation coil is structured to generate magnetic flux in a direction of the harvester core. 4. The circuit interrupter of claim 3 , wherein by generating the magnetic flux in the direction of the harvester core, the compensation coil is structured to prevent linking magnetic flux of external magnetic field generated by at least the harvester core to the Rogowski until the second input current level is reached. 5. The circuit interrupter of claim 4 , wherein the compensation coil provides a fully automatic compensation for deviation of linearity. 6. The circuit interrupter of claim 5 , wherein the fully automatic compensation comprises an automatic measurement of a single calibration factor for correcting an error in the output of the Rogowski coil based at least in part on the saturation of the harvester core at the second input current level. 7. The circuit interrupter of claim 1 , the Rogowski coil comprises a plurality of number of turns and two-degree error in winding, each turn being represented as a slit and the two degree error in winding comprising seven slits. 8. The circuit interrupter of claim 7 , wherein a first error rate of the Rogowski coil with the compensation coil is lower than a second error rate of the Rogowski coil without the compensation coil, the first error rate exhibits a sudden change in error rate over a first range starting from the first input current level, and the second error rate remains constant over the range of input current levels, the sudden change indicative of the deviation of the linearity greater than the deviation tolerance. 9. The circuit interrupter of claim 1 , wherein the deviation tolerance is 0.25% where 0% equal to perfect linearity. 10. A circuit interrupter structured to electrically connect between a power source coupled to a hot conductor and a load coupled to a load conductor, the circuit interrupter comprising: (a) separable contacts; (b) an operating mechanism coupled to the separable contacts; (c) an electronic trip unit coupled to the operating mechanism; and (d) a current sensor assembly comprising: (i) a harvester circuit comprising a harvester core, a primary conductor through which input current from the power source flows, and a secondary winding wound around a first part of the harvester core, the harvester circuit structured to harvest power from the power source and supply power to at least the operating mechanism and the electronic trip unit, wherein the harvester core saturates at a first input current level of a range of input current levels; (ii) a Rogowski coil comprising a toroid through the center of which the primary conductor passes, the Rogowski coil structured to measure voltage at an output of the Rogowski coil, the measured voltage indicative of output current of Rogowski coil, wherein linearity of the output of Rogowski coil to the input current deviates more than a deviation tolerance based at least in part on saturation of the harvester core at the first input current level, and (iii) a magnetic shielding made of magnetic material having a high permeability, the magnetic shielding arranged between the Rogowski coil and the harvester circuit and structured to isolate the non-linearity source from the Rogowski coil, wherein the electronic trip unit is structured to receive a signal including the measured voltage from the Rogowski coil, and cause the operating mechanism to open the separable contacts and interrupt current flowing through the circuit interrupter based at least in part on the measured voltage. 11. The circuit interrupter of claim 10 , wherein the magnetic material comprises has a high relative permeability greater than 10,000. 12. The circuit interrupter of claim 10 , wherein to isolate the non-linearity source from the Rogowski coil, the magnetic shielding is structured to generate a return path for magnetic flux of the external magnetic field generated by the non-linearity source. 13. The circuit interrupter of claim 12 , wherein the magnetic shielding is further structured to accommodate the magnetic flux lines of the external magnetic field to travel through the magnetic material to the non-linearity source via the return path. 14. The circuit interrupter of claim 12 , wherein the magnetic shielding absorbs the external magnetic field by preventing the magnetic flux lines to return to the non-linearity source via the air around the magnetic shielding. 15. The circuit interrupter of claim 10 , wherein the magnetic material comprises a mumetal alloy. 16. The circuit interrupter of claim 10 , wherein the Rogowski coil comprises non-uniform winding. 17. The circuit interrupter of claim 16 , wherein a first error rate of the Rogowski coil measured with the magnetic shielding present is lower than a second error rate of the Rogowski coil without the magnetic shielding, the first error rate exhibits a sudden change in the error rate over a first range starting from the first input current level, and the second error rate remains constant over the range of input current levels, the sudden change indicative of the deviation of the linearity greater than the deviation tolerance. 18. A method of improving linearity of a current sensor and accuracy of a circuit interrupter including a Rogowski coil for sensing load current, a harvester circuit having a ferromagnetic core, a primary conductor, and a secondary winding, and a compensation coil arranged 180 degree opposite to the secondary winding, compri