Driver circuit for an electric vehicle and a diagnostic method for determining when a first voltage driver is shorted to a high voltage and a second voltage driver has a low electrical current flowing therethrough

What is claimed is: 1. A driver circuit for an electric vehicle, comprising: a first voltage driver having a first input line, a first output line, and a first voltage sense line; the first input line coupled to both the first voltage driver and a microprocessor, the first output line coupled to a first side of a contactor coil of a contactor, the first voltage sense line coupled to both the first output line and to the microprocessor; a second voltage driver having a second input line, a second output line, and a second voltage sense line; the second input line coupled to the microprocessor, the second output line coupled to a second side of the contactor coil, the second voltage sense line coupled to the microprocessor; the microprocessor configured to generate a first pulse width modulated signal on the first input line to induce the first voltage driver to output a second pulse width modulated signal on the first output line that is received by the first side of the contactor coil to energize the contactor coil; the microprocessor further configured to iteratively measure a voltage on the first voltage sense line over time to obtain a first plurality of voltage values when the microprocessor is generating the first pulse width modulated signal; the microprocessor further configured to determine a first filtered voltage value based on the first plurality of voltage values; the microprocessor further configured to set a first diagnostic flag equal to a first value if the first filtered voltage value is greater than a first threshold value; the microprocessor further configured to iteratively measure a voltage on the second voltage sense line over time that is indicative of a voltage on the second output line to obtain a second plurality of voltage values when the microprocessor is generating the first pulse width modulated signal; the microprocessor further configured to determine a first filtered current value based on the second plurality of voltage values, the first filtered current value indicative of an amount of electrical current flowing through the contactor coil; the microprocessor further configured to set a second diagnostic flag equal to a second value if the first filtered current value is less than a second threshold value; and the microprocessor further configured to stop generating the first pulse width modulated signal to de-energize the contactor coil if the first diagnostic flag is set equal to the first value, and the second diagnostic flag is set equal to the second value. 2. The driver circuit of claim 1 , wherein the microprocessor is further configured to generate a first signal on the second input line to induce the second voltage driver to receive the electrical current from the contactor coil on the second output line to energize the contactor coil. 3. The driver circuit of claim 2 , wherein the microprocessor is further configured to stop generating the first signal to de-energize the contactor coil if the first diagnostic flag is set equal to the first value, and the second diagnostic flag is set equal to the second value. 4. The driver circuit of claim 2 , wherein the first signal has a high logic voltage while the first pulse width modulated signal is being generated. 5. The driver circuit of claim 1 , wherein when the first diagnostic flag is set equal to the first value and the second diagnostic flag is set equal to the second value, the first and second diagnostic flags indicate that the amount of electrical current flowing through the contactor coil is less than a desired electrical current level that maintains a closed operational state of the contactor. 6. The driver circuit of claim 1 , wherein the second voltage sense line is electrically coupled to the second output line utilizing a transistor. 7. A diagnostic method for a driver circuit for an electric vehicle, the driver circuit having a first voltage driver, a second voltage driver, and a microprocessor; the first voltage driver having a first input line, a first output line, and a first voltage sense line; the first input line coupled to both the first voltage driver and the microprocessor, the first output line coupled to a first side of a contactor coil of a contactor, the first voltage sense line coupled to both the first output line and to the microprocessor; the second voltage driver having a second input line, a second output line, and a second voltage sense line; the second input line coupled to the microprocessor, the second output line coupled to a second side of the contactor coil, the second voltage sense line coupled to the microprocessor; the method comprising: generating a first pulse width modulated signal on the first input line utilizing the microprocessor to induce the first voltage driver to output a second pulse width modulated signal on the first output line that is received by the first side of the contactor coil to energize the contactor coil; iteratively measuring a voltage on the first voltage sense line over time to obtain a first plurality of voltage values utilizing the microprocessor when the microprocessor is generating the first pulse width modulated signal; determining a first filtered voltage value based on the first plurality of voltage values utilizing the microprocessor; setting a first diagnostic flag equal to a first value if the first filtered voltage value is greater than a first threshold value utilizing the microprocessor; iteratively measuring a voltage on the second voltage sense line over time that is indicative of a voltage on the second output line utilizing the microprocessor to obtain a second plurality of voltage values when the microprocessor is generating the first pulse width modulated signal; determining a first filtered current value based on the second plurality of voltage values utilizing the microprocessor, the first filtered current value indicative of an amount of electrical current flowing through the contactor coil; setting a second diagnostic flag equal to a second value if the first filtered current value is less than a second threshold value utilizing the microprocessor; and stopping the generating of the first pulse width modulated signal to de-energize the contactor coil if the first diagnostic flag is set equal to the first value and the second diagnostic flag is set equal to the second value, utilizing the microprocessor. 8. The diagnostic method of claim 7 , further comprising generating a first signal on the second input line utilizing the microprocessor to induce the second voltage driver to receive the electrical current from the contactor coil on the second output line to energize the contactor coil. 9. The diagnostic method of claim 8 , further comprising stopping the generating of the first signal to de-energize the contactor coil utilizing the microprocessor if the first diagnostic flag is set equal to the first value, and the second diagnostic flag is set equal to the second value. 10. The diagnostic method of claim 8 , wherein the first signal has a high logic voltage while the first pulse width modulated signal is being generated. 11. The diagnostic method of claim 7 , wherein when the first diagnostic flag is set equal to the first value and the second diagnostic flag is set equal to the second value, the first and second diagnostic flags indicate that the amount of electrical current flowing through the contactor coil is less than a desired electrical current level that maintains a closed operational state of the contactor. 12. The diagnostic method of claim 7 , further comprising turning on a transistor to electrically couple the second voltage sense line to the second output line.