Electric grill with current protection circuitry

What is claimed is: 1. A circuit, comprising: a first and second heating element connected to a voltage line through a first and second triac, respectively, and further connected to a neutral line; a first and second control knob for selecting a high, medium, or low operating mode of the first and second heating element, respectively; a display configured to display the first and second selected operating mode; at least one latch connected between the heating elements and the voltage line, the latch being connected to a trip controller through a control line; a current transformer configured to measure a difference in current between the voltage line and the neutral line and connected through a control line to a ground fault detection unit; a control line connecting the ground fault detection unit and the trip controller; a microprocessor connected to a memory, the first and second control knob, and further connected to a first triac driver and a second triac driver; the first and second triac drivers being respectively connected to the first and second triacs, respectively; and at least one Hall Effect sensor configured to measure the current delivered to the first and second heating element, and to communicate a first and second measured current to the microprocessor; wherein the microprocessor is configured to access the memory to retrieve a first and second expected current associated with the selected high, medium, or low operating mode of the first and second heating element compare the first and second measured current with the expected current for the first and second heating element, respectively; disable the latch in response to a first or second measured current that is higher or lower than the first or second expected current, respectively; and alert a user, via the display, that the flow of current has been disabled. 2. The circuit of claim 1 , wherein the microprocessor is configured to disable at least one triac driver in response to a current reading from a Hall Effect sensor which exceeds a predetermined current threshold. 3. The circuit of claim 2 , further comprising a watchdog monitor connected to the microprocessor and further connected to the first and second triacs. 4. The circuit of claim 3 , further comprising a first and second thermocouple proximately located respectively at the first and second heating element and in communication with the microprocessor. 5. A method for protecting an electric circuit, comprising the steps of: using at least a first control knob to select high, medium, or low operating mode of one or more heating elements; displaying, on a display, the selected operating mode; delivering current associated with said operating mode to the one or more electric heating elements connected to a voltage line and a neutral line through a triac and a latch relay; using a current transformer to measure a current difference between the voltage line and the neutral line; and generating an electric signal indicating the current difference and responding to said current difference by activating a trip controller connected to the latch relay; using a Hall Effect sensor to measure a current passing through the triac and sending a signal indicative of the measured current passing through the triac to a microprocessor; using the microprocessor to access a memory to retrieve an expected current associated with the selected high, medium, or low operating mode of the one or more heating elements; comparing the measured current with the expected current of the one or more heating elements; disabling the latch relay in response to a measured current that is higher or lower than the expected current of the one or more heating elements; and alerting a user, via the display, that the flow of current has been disabled. 6. The method of claim 5 , further comprising the step of responding to a current passing through the triac that exceeds a predetermined current threshold by disabling the flow of electricity to the one or more electric heating elements. 7. The method of claim 6 , further comprising the step of selecting the predetermined current threshold in response to an operating mode received through a user input. 8. The method of claim 5 , further comprising the steps of: sending a signal indicative of normal operation from the microprocessor to a watchdog monitor; and sending an enable signal from the watchdog monitor to said triac in response to said signal indicative of normal operation. 9. An electric grill, comprising: a housing having two user inputs configured to select a first and second high, medium, or low operating mode, and a display configured to display the first and second selected operating mode; an electric cord connected to a voltage line and a neutral line; at least two heating elements respectively connected to a first and second triac and further connected to the voltage line and neutral line; a microprocessor connected to a first and second triac driver, the first and second triac drivers respectively in communication with the first and second triac, the microprocessor configured to deliver a current associated with the first and second selected operating mode to the first and second heating elements; a Hall Effect sensor configured to measure the current delivered to the first and second heating element and to communicate a first and second measured current to the microprocessor; wherein the microprocessor is configured to access a memory to retrieve a first and second expected current associated with the selected high, medium, or low operating mode of the first and second heating element compare the first and second measured current with the expected current for the first and second heating element disable the flow of current to the first and second heating element in response to a first or second measured current that is higher or lower than the first or second expected current and alert a user, via the display, that the flow of current has been disabled. 10. The electric grill of claim 9 , further comprising: a current transformer configured to measure a current difference between the voltage line and the neutral line, said current transformer in communication with a ground fault detection unit; and a trip controller in communication with the ground fault detection unit, and further in communication with at least one latch connected between the first and second triac and the voltage line. 11. An electric grill, comprising: a housing having one or more user inputs for selecting a high, medium, or low operating mode of a heating element, and a display configured to display the selected operating mode; an electric cord connected to a voltage line and a neutral line; the heating element being connected to a triac and further connected to the voltage line and neutral line; at least one latch relay connected between the heating element and the voltage line, the latch relay being in communication with a trip controller; a ground fault detection unit in communication with the trip controller and configured to activate the trip controller in response to an unbalanced current between the voltage line and the neutral line; a microprocessor connected to a triac driver, the triac driver being in communication with the triac, wherein the microprocessor activates the triac driver to deliver a current associated with the selected operating mode; and a current sensor configured to measure current passing through the triac, the current sensor communicating a measured current to the microprocessor; wherein the microprocessor is configured to access a memory to retrieve an expected current associated with the selected high, me