Techniques for segmented monitoring of powertrain propulsive torque in electrified vehicles

What is claimed is: 1. A control system for an electrified powertrain of an electrified vehicle, the control system comprising: a main control system configured to perform a sequence of first processes based on an initial input including a set of signals indicative of at least one of a driver torque request and expected vehicle behavior and other intermediary inputs to generate a sequence of first outputs; and a secondary monitoring system distinct from the main control system and configured to perform a sequence of second processes based on the initial input and other intermediary inputs to generate a sequence of second outputs and to: rationalize each first output by comparing it to its respective second output; when rationalized, using the particular first output as a subsequent intermediary input for both the main control system and the secondary monitoring system; when not rationalized, using the particular second output as the subsequent intermediary input; and using a rationalized final first output or a final second output to generate control commands for torque actuators of the electrified powertrain, wherein the rationalizing of the first outputs during the sequences of first and second processes is configured to reduce or eliminate false positive malfunction detections in the main control system. 2. The control system of claim 1 , wherein the secondary monitoring system is further configured to generate a flag or increment a counter for every first output that is not rationalized. 3. The control system of claim 2 , wherein the secondary monitoring system is further configured to generate the flag or increment the counter for every first output that is not rationalized and also exceeds upper/lower boundary metrics. 4. The control system of claim 2 , wherein the secondary monitoring system is further configured to detect a positive malfunction in the main control system when a quantity of flags or the counter exceeds a calibratable threshold. 5. The control system of claim 4 , wherein the secondary monitoring system is further configured to command a limited limp-home mode or fully disable the electrified vehicle upon detecting the positive malfunction in the main control system. 6. The control system of claim 1 , wherein the sequences of first and second processes include at least one of accelerator pedal sensor voltage determination, accelerator pedal depression percentage, and desired powertrain propulsive torque. 7. The control system of claim 6 , wherein the sequences of first and second processes include at least the accelerator pedal sensor voltage determination, the accelerator pedal depression percentage, and the desired powertrain propulsive torque. 8. The control system of claim 1 , wherein at least the sequence of first processes are based on at least one of battery current and battery temperature, and wherein a high voltage shock incident causes a particular first output to not be rationalized. 9. The control system of claim 1 , wherein the main control system and the secondary monitoring system are distinct from each other and are executed in parallel by two processors or by two cores of a single processor. 10. A control method for an electrified powertrain of an electrified vehicle, the control method comprising: performing, by a main control system, a sequence of first processes based on an initial input including a set of signals indicative of at least one of a driver torque request and expected vehicle behavior and other intermediary inputs to generate a sequence of first outputs; performing, by a secondary monitoring system distinct from the main control system, a sequence of second processes based on the initial input and other intermediary inputs to generate a sequence of second outputs; rationalizing, by the secondary monitoring system, each first output by comparing it to its respective second output; when rationalized, using, by the secondary monitoring system, the particular first output as a subsequent intermediary input for both the main control system and the secondary monitoring system; when not rationalized, using, by the secondary monitoring system, the particular second output as the subsequent intermediary input; and using, by the secondary monitoring system, a rationalized final first output or a final second output to generate control commands for torque actuators of the electrified powertrain, wherein the rationalizing of the first outputs during the sequences of first and second processes is configured to reduce or eliminate false positive malfunction detections in the main control system. 11. The control method of claim 10 , wherein the secondary monitoring system is further configured to generate a flag or increment a counter for every first output that is not rationalized. 12. The control method of claim 11 , wherein the secondary monitoring system is further configured to generate the flag or increment the counter for every first output that is not rationalized and also exceeds upper/lower boundary metrics. 13. The control method of claim 11 , wherein the secondary monitoring system is further configured to detect a positive malfunction in the main control system when a quantity of flags or the counter exceeds a calibratable threshold. 14. The control method of claim 13 , wherein the secondary monitoring system is further configured to command a limited limp-home mode or fully disable the electrified vehicle upon detecting the positive malfunction in the main control system. 15. The control method of claim 10 , wherein the sequences of first and second processes include at least one of accelerator pedal sensor voltage determination, accelerator pedal depression percentage, and desired powertrain propulsive torque. 16. The control method of claim 15 , wherein the sequences of first and second processes include at least the accelerator pedal sensor voltage determination, the accelerator pedal depression percentage, and the desired powertrain propulsive torque. 17. The control method of claim 10 , wherein at least the sequence of first processes are based on at least one of battery current and battery temperature, and wherein a high voltage shock incident causes a particular first output to not be rationalized. 18. The control method of claim 10 , wherein the main control system and the secondary monitoring system are distinct from each other and are executed in parallel by two processors or by two cores of a single processor.