Drain-to-source monitoring of power switches in a half-bridge during runtime

The invention claimed is: 1. A driver circuit configured to control a half-bridge that includes a high-side power switch and a low-side power switch, the driver circuit comprising: a high-side compare unit configured to determine a first drain-to-source voltage, wherein the first drain-to-source voltage is associated with the high-side power switch when the high-side power switch is ON; and a low-side compare unit configured to determine a second drain-to-source voltage, wherein the second drain-to-source voltage is associated with the low-side power switch when the low-side power switch is ON, wherein the high-side compare unit is further configured to determine a third drain-to-source voltage, wherein the third drain-to-source voltage is associated with the high-side power switch when the high-side power switch is OFF, and wherein the low-side compare unit is further configured to determine a fourth drain-to-source voltage, wherein the fourth drain-to-source voltage is associated with the low-side power switch when the low-side power switch is OFF. 2. The driver circuit of claim 1 , wherein the driver circuit is configured to output one or more fault signals to a control unit based on one or more of the determinations. 3. The driver circuit of claim 2 , wherein the driver circuit is configured to: output a first power switch fault signal to the control unit in response to the first drain-to-source voltage being higher than a first drain-to-source threshold; and output a second power switch fault signal to the control unit in response to the second drain-to-source voltage being higher than a second drain-to-source threshold. 4. The driver circuit of claim 3 , wherein the driver circuit is configured to disable or limit operation of the half-bridge in response to outputting the first or second power switch fault signals. 5. The driver circuit of claim 3 , wherein the driver circuit is further configured to: output a first comparator fault signal to the control unit in response to the third drain-to-source voltage being lower than a third drain-to-source threshold; and output a second comparator fault signal to the control unit in response to the fourth drain-to-source voltage being lower than a fourth drain-to-source threshold. 6. The driver circuit of claim 5 , wherein the first drain-to-source threshold is equal to the second drain-to-source threshold, and wherein the third drain-to-source threshold is equal to the fourth drain-to-source threshold. 7. The driver circuit of claim 6 , wherein the first and second drain-to-source thresholds are different than the third and fourth drain-to-source thresholds. 8. The driver circuit of claim 1 , wherein the driver circuit is configured to control ON/OFF states of the first and second power switches via first and second gate signals delivered to the first and second power switches. 9. The driver circuit of claim 1 , further comprising a plurality of driver circuits configured to control a plurality of half-bridges. 10. The driver circuit of claim 9 , wherein the plurality of half-bridges is configured to control a multi-phase electric motor. 11. A system comprising: a control unit; and a driver circuit configured to receive control signals from the control unit and to control a half-bridge based on the control signals, wherein the half-bridge includes a high-side power switch and a low-side power switch, the driver circuit comprising: a high-side compare unit configured to determine a first drain-to-source voltage, wherein the first drain-to-source voltage is associated with the high-side power switch when the high-side power switch is ON; and a low-side compare unit configured to determine a second drain-to-source voltage, wherein the second drain-to-source voltage is associated with the low-side power switch when the low-side power switch is ON, wherein the high-side compare unit is further configured to determine a third drain-to-source voltage, wherein the third drain-to-source voltage is associated with the high-side power switch when the high-side power switch is OFF, and wherein the low-side compare unit is further configured to determine a fourth drain-to-source voltage, wherein the fourth drain-to-source voltage is associated with the low-side power switch when the low-side power switch is OFF. 12. The system of claim 11 , the system further comprising the high-side power switch and the low-side power switch. 13. The system of claim 11 , wherein the driver circuit is configured to: output a first power switch fault signal to the control unit in response to the first drain-to-source voltage being higher than a first drain-to-source threshold; and output a second power switch fault signal to the control unit in response to the second drain-to-source voltage being higher than a second drain-to-source threshold. 14. The system of claim 13 , wherein the control unit is configured to disable or limit operation of the half-bridge in response to receiving the first power switch fault signal or the second power switch fault signal. 15. The system of claim 13 , wherein the driver circuit is further configured to: output a first comparator fault signal to the control unit in response to the third drain-to-source voltage being lower than a third drain-to-source threshold; and output a second comparator fault signal to the control unit in response to the fourth drain-to-source voltage being lower than a fourth drain-to-source threshold. 16. The system of claim 15 , wherein the control unit is configured to issue a maintenance alert for the system in response to receiving the first comparator fault signal or the second comparator fault signal. 17. The system of claim 11 , further comprising a plurality of driver circuits configured to control a plurality of half-bridges, wherein the plurality of half-bridges is configured control a multi-phase electric motor. 18. The system of claim 17 , the system further comprising the multi-phase electric motor. 19. A method of controlling a half-bridge that includes a high-side power switch and a low-side power switch, the method comprising: determining a first drain-to-source voltage, wherein the first drain-to-source voltage is associated with the high-side power switch when the high-side power switch is ON; determining a second drain-to-source voltage, wherein the second drain-to-source voltage is associated with the low-side power switch when the low-side power switch is ON; determining a third drain-to-source voltage, wherein the third drain-to-source voltage is associated with the high-side power switch when the high-side power switch is OFF; and determining a fourth drain-to-source voltage, wherein the fourth drain-to-source voltage is associated with the low-side power switch when the low-side power switch is OFF. 20. The method of claim 19 , further comprising: outputting a first power switch fault signal to a control unit in response to the first drain-to-source voltage being higher than a first drain-to-source threshold; outputting a second power switch fault signal to the control unit in response to the second drain-to-source voltage being higher than a second drain-to-source threshold; and issuing a power switch alert via the control unit in response to the control unit receiving the first power switch fault signal or the second power switch fault signal. 21. The method of claim 19 , further comprising: outputting a first comparator fault signal to a control unit in response to