Diagnostic system for a DC-DC voltage converter

What is claimed is: 1. A diagnostic system for a DC-DC voltage converter, comprising: a microcontroller having a first diagnostic handler application, first and second applications, and a safe state application; the first application setting a first non-recoverable diagnostic flag associated with the DC-DC voltage converter to a first encoded value and sending the first non-recoverable diagnostic flag to the first diagnostic handler application; the first encoded value having each nibble thereof selected from an odd Karnaugh set of binary values; the second application setting a second non-recoverable diagnostic flag associated with the DC-DC voltage converter to a second encoded value and sending the second non-recoverable diagnostic flag to the first diagnostic handler application; the second encoded value having each nibble thereof selected from an even Karnaugh set of binary values; the first diagnostic handler application setting a first master non-recoverable diagnostic flag associated with the DC-DC voltage converter to a first encoded fault value if the first non-recoverable diagnostic flag is equal to a second encoded fault value, or the second non-recoverable diagnostic flag is equal to a third encoded fault value; the first diagnostic handler application sending the first mater non-recoverable diagnostic flag to the safe state application; the safe state application transitioning a high voltage switch and a low voltage switch in the DC-DC voltage converter to an open operational state, and a contactor to an open operational state, if the first mater non-recoverable diagnostic flag is equal to the first encoded fault value; wherein each of the first and second non-recoverable diagnostic flags is a flag which when set to an encoded fault value induces the diagnostic system to take safe action by transitioning the high voltage switch and the low voltage switch in the DC-DC voltage converter to the open operational state, and to transition the contractor to the open operational state to electrically de-couple a battery pack from a vehicle electric load, and the diagnostic system thereafter maintains the high voltage switch, the low voltage switch, and the contactor in the open operational state even if the first and second non-recoverable diagnostic flags are set to an encoded non-fault value; wherein the off Karnaugh set of values corresponds to numbers having corresponding binary numbers with an off number of 0 bits and an off number of 1 bits in a nibble, and the even Karnaugh set of values corresponds to numbers having corresponding binary numbers with an even number of 0 bits and an even number of 1 bits in a nibble for numbers greater than zero. 2. The diagnostic system of claim 1 , wherein: the microcontroller having a third application, the third application setting a first recoverable diagnostic flag associated with the DC-DC voltage converter to a third encoded value and sending the first recoverable diagnostic flag to the first diagnostic handler application; and the first diagnostic handler application setting a first master recoverable diagnostic flag associated with the DC-DC voltage converter to a fourth encoded fault value if the first recoverable diagnostic flag is equal to a fifth encoded fault value; wherein the first recoverable diagnostic flag is a flag which when set to an encoded fault value indices the diagnostic system to take safe action by transitioning the high voltage switch and the low voltage switch in the DC-DC voltage converter to the open operation state, and to transition the contractor to the open operational state to electrically de-couple the batter pack from the vehicle electrical load, and the diagnostic system thereafter transitions the high voltage switch, the low voltage switch, and the contactor to the closed operational state if the first recoverable diagnostic flag is set to an encoded non-fault value. 3. The diagnostic system of claim 2 , wherein: the first diagnostic handler application sending the first master recoverable diagnostic flag to the safe state application; and the safe state application transitioning the high voltage switch and the low voltage switch in the DC-DC voltage converter to the open operational state if the first master recoverable diagnostic flag is equal to the fourth encoded fault value. 4. The diagnostic system of claim 3 , wherein the safe state application transitioning the contactor to the open operational state if the first master recoverable diagnostic flag is equal to the fourth encoded fault value. 5. The diagnostic system of claim 2 , wherein: the microcontroller having a second diagnostic handler application and fourth and fifth applications; the fourth application setting a third non-recoverable diagnostic flag associated with the DC-DC voltage converter to a fourth encoded value and sending the third non-recoverable diagnostic flag to the second diagnostic handler application; the fourth encoded value having each nibble thereof selected from the odd Karnaugh set of binary values; the fifth application setting a fourth non-recoverable diagnostic flag associated with the DC-DC voltage converter to a fifth encoded value and sending the fourth non-recoverable diagnostic flag to the second diagnostic handler application; the fifth encoded value having each nibble thereof selected from the even Karnaugh set of binary values; and the second diagnostic handler application setting a second master non-recoverable diagnostic flag associated with the DC-DC voltage converter to a sixth encoded fault value if the third non-recoverable diagnostic flag is equal to a seventh encoded fault value, or the fourth non-recoverable diagnostic flag is equal to an eighth encoded fault value; wherein the second recoverable diagnostic flag is a flag which when set to an encoded fault value induces the diagnostic system to take safe action by transitioning the high voltage switch and the low voltage switch in the DC-DC voltage converter to the open operational state, and to transition the contactor to the open operational state to electrically de-couple the battery pack from the vehicle electrical load, and the diagnostic system thereafter transitions the high voltage switch, the low voltage switch, and the contactor to a closed operational state if the second recoverable diagnostic flag is set to an encoded non-fault value. 6. The diagnostic system of claim 5 , wherein: the second diagnostic handler application sending the second master non-recoverable diagnostic flag to the safe state application; and the safe state application transitioning the high voltage switch and the low voltage switch in the DC-DC voltage converter to the open operational state if the second master non-recoverable diagnostic flag is equal to the sixth encoded fault value. 7. The diagnostic system of claim 6 , wherein the safe state application transitioning the contactor to the open operational state if the second master non-recoverable diagnostic flag is equal to the sixth encoded fault value. 8. The diagnostic system of claim 5 , wherein: the microcontroller having a sixth application, the sixth application setting a second recoverable diagnostic flag associated with the DC-DC voltage converter to a sixth encoded value and sending the second recoverable diagnostic flag to the second diagnostic handler application; and the second diagnostic handler application setting a second master recoverable diagnostic flag associated with the DC-DC voltage converter to a ninth encoded fault value if the second recoverable diagnostic flag is equal to a tenth encoded fault value; wherein the second recoverable diagnostic flag is a flag which when set to an encoded fault value induces the diagnostic system to take sa