Control system for transitioning a DC-DC voltage converter from a buck operational mode to a safe operational mode

What is claimed is: 1. A control system for transitioning a DC-DC voltage converter from a buck operational mode to a safe operational mode, the DC-DC voltage converter having a high voltage switch, a low voltage switch, and a DC-DC voltage converter control circuit with a high side integrated circuit and a low side integrated circuit therein, the DC-DC voltage converter control circuit being electrically coupled between the high voltage switch and the low voltage switch; the high side integrated circuit having a first plurality of FET switches therein, the low side integrated circuit having a second plurality of FET switches therein, comprising: a microcontroller having a first application and a second application; the first application commanding the microcontroller to generate a first control signal that is received at a first input pin on the high side integrated circuit to command the high side integrated circuit to transition each of the first plurality of FET switches therein to an open operational state, the first control signal being further received at a first input pin on the low side integrated circuit to command the low side integrated circuit to transition each of the second plurality of FET switches therein to the open operational state; and the second application commanding the microcontroller to generate a second control signal that is received at a second input pin on the high side integrated circuit to command the high side integrated circuit to transition each of the first plurality of FET switches therein to the open operational state, the second control signal being further received at a second input pin on the low side integrated circuit to command the low side integrated circuit to transition each of the second plurality of FET switches therein to the open operational state. 2. The control system of claim 1 , wherein: the second application commanding the microcontroller to generate a third control signal to transition the low voltage switch to the open operational state; and the second application commanding the microcontroller to generate a fourth control signal to transition the pre-charge low voltage switch to the open operational state. 3. The control system of claim 1 , wherein the microcontroller receiving a first confirmation signal from at least one of an output pin of the high side integrated circuit and an output pin of the low side integrated circuit, the second application determining that at least one of the first plurality of FET switches and the second plurality of FET switches are transitioned to the open operational state based on the first confirmation signal. 4. The control system of claim 1 , wherein: the DC-DC voltage converter further includes a pre-charge high voltage switch and a pre-charge low voltage switch; the low voltage switch being electrically coupled in parallel to the pre-charge low voltage switch; and the high voltage switch being electrically coupled in parallel to the pre-charge high voltage switch. 5. The control system of claim 2 , further comprising: a first voltage sensor electrically coupled to a first electrical node between the DC-DC voltage converter control circuit and the low voltage switch, the first voltage sensor outputting a first voltage measurement signal indicating a first voltage at the first electrical node, the first voltage measurement signal being received by the microcontroller; a second voltage sensor electrically coupled to a second electrical node between the low voltage switch and a first battery, the second voltage sensor outputting a second voltage measurement signal indicating a second voltage at the second electrical node, the second voltage measurement signal being received by the microcontroller; the microcontroller determining first and second voltage values, respectively, based on the first and second voltage measurement signals, respectively; and the microcontroller further having a third application which determines that the low voltage switch and a pre-charge low voltage switch have each been transitioned to the open operational state, if an absolute value of a difference between the first and second voltage values is greater than a first threshold voltage value. 6. The control system of claim 5 , wherein: the third application commanding the microcontroller to generate a fifth control signal to transition the high voltage switch to the open operational state; and the third application commanding the microcontroller to generate a sixth control signal to transition the pre-charge high voltage switch to the open operational state. 7. The control system of claim 6 , further comprising: a third voltage sensor electrically coupled to a third electrical node between a second battery and the high voltage switch, the third voltage sensor outputting a third voltage measurement signal indicating a third voltage at the third electrical node, the third voltage measurement signal being received by the microcontroller; and a fourth voltage sensor electrically coupled to a fourth electrical node between the high voltage switch and the DC-DC voltage converter control circuit, the fourth voltage sensor outputting a fourth voltage measurement signal indicating a fourth voltage at the fourth electrical node, the fourth voltage measurement signal being received by the microcontroller; the microcontroller determining third and fourth voltage values, respectively, based on the third and fourth voltage measurement signals, respectively; and the microcontroller having a fourth application which determines that the high voltage switch and a pre-charge high voltage switch have each been transitioned to the open operational state, if an absolute value of a difference between the third and fourth voltage values is greater than a second threshold voltage value.