Energy monitoring device

What is claimed is: 1. An energy monitoring device comprising: a power supply circuit electrically coupled to a power source via a hot conductor and a load via a load conductor; a relay circuit comprising a relay and a relay driver circuit electrically coupled to the relay and configured to drive the relay, wherein the relay comprises a relay contact and a plurality of coils, and the relay contact is electrically coupled to the hot conductor and the load conductor; a sensing circuit comprising a hot voltage sensor electrically coupled to the power source and a load voltage sensor electrically coupled to the load conductor; and a controller comprising an analog to digital converter, and electrically coupled to the power supply circuit, the relay driver circuit, and the sensing circuit, wherein the controller is structured to receive a hot voltage from the hot voltage sensor and a load voltage from the load voltage sensor, and determine a load current based at least in part on a relay contact resistance of the relay contact and a delta between the hot voltage and the load voltage. 2. The energy monitoring device of claim 1 , wherein the controller is structured to determine the delta based at least in part on the relay contact being closed. 3. The energy monitoring device of claim 1 , wherein the plurality of coils comprises a first coil and a second coil, and the relay driver circuit comprises a first switch electrically couplable to the first coil and the power supply circuit and a second switch electrically couplable to the second coil and the power supply circuit. 4. The energy monitoring device of claim 3 , wherein the relay contact is closed based on the first coil being energized by a voltage output from the power supply circuit via the first switch upon closing of the first switch. 5. The energy monitoring device of claim 4 , wherein the relay contact is open based on the second coil being energized by the voltage output via the second switch upon closing of the second switch and opening of the first switch. 6. The energy monitoring device of claim 1 , wherein the sensing circuit comprises a half bridge rectifier, a voltage divider, and a fixed gain differential amplifier. 7. The energy monitoring device of claim 6 , wherein the sensing circuit transmits a voltage output from the fixed gain differential amplifier to the controller. 8. The energy monitoring device of claim 1 , wherein the sensing circuit further comprises a temperature sensor electrically coupled to the controller and structured to transmit a voltage signal to the controller. 9. The energy monitoring device of claim 8 , wherein the controller is structured to determine an instant ambient temperature based on the voltage signal in accordance with a look-up table stored in memory of the controller. 10. The energy monitoring device of claim 9 , wherein the controller is further structured to adjust the relay contact resistance based on the determined ambient temperature and calculate the load current based on the delta and the adjusted relay contact resistance. 11. The energy monitoring device of claim 1 , wherein the relay contact resistance is an average relay contact resistance. 12. The energy monitoring device of claim 11 , wherein the controller is configured to obtain the average relay contact resistance by obtaining an average of a plurality of relay contact resistances measured upon passing a plurality of current via the relay contact. 13. The energy monitoring device of claim 12 , wherein the plurality of current comprises at least a first current comprising a low current and a second current comprising a high current. 14. The energy monitoring device of claim 13 , wherein the controller is configured to obtain a plurality of deltas between respective hot voltages and load voltages, including at least a first delta based on the first current and a second delta based on the second current. 15. The energy monitoring device of claim 14 , wherein the plurality of relay contact resistance comprises at least a first relay contact resistance based on the first delta and the first current and a second relay contact resistance based on the second delta and the second current. 16. The energy monitoring device of claim 1 , wherein the sensing circuit further comprises a zero crossing detector circuit. 17. An energy monitoring device comprising: a power supply circuit electrically coupled to a power source via a hot conductor and a load via a load conductor; a relay circuit comprising a relay and a relay driver circuit electrically coupled to the relay and configured to drive the relay, wherein the relay comprises a relay contact and a plurality of coils, and the relay contact is electrically coupled to the hot conductor and the load conductor; a sensing circuit comprising a differential voltage amplifier circuit, wherein the differential voltage amplifier circuit comprises a differential operational amplifier (OPAMP), one input terminal of the OPAM is coupled to the power source and structured to receive hot voltage sensed at the hot conductor, the other input terminal of the OPAMP is coupled to the load and structured to receive load voltage sensed at the load conductor, and the output terminal of the OPAMP is structured to provide a voltage output representative of a delta between the hot voltage and the load voltage; and a controller comprising an analog to digital converter, and electrically coupled to the power supply circuit, the relay driver circuit, and the sensing circuit, wherein the controller is structured to receive the delta between the hot voltage and the load voltage from the differential voltage amplifier circuit, and determine a load current based at least in part on a relay contact resistance of the relay contact and the delta. 18. A method for energy monitoring, comprising: measuring, by a sensing circuit of an energy monitoring device, a hot voltage and a load voltage of an energy monitoring device; transmitting, by the sensing circuit, the measured hot voltage and the measured load voltage to a controller of the energy monitoring device; determining, by the controller, a delta between the hot voltage and the load voltage; retrieving, by the controller, a relay contact resistance from memory of the controller; and determining a load current based on the delta and the relay contact resistance. 19. The method of claim 18 , further comprising adjusting the relay contact resistance based on an instant ambient temperature determined based on a voltage signal received from a temperature sensor. 20. The method of claim 19 , wherein the load current is determined based on the delta and the adjusted relay contact resistance.