Vehicle thermal systems low to high quality energy management, storage, recovery, and optimization

What is claimed is: 1. A method for continuously managing thermal energy in a motor vehicle comprises: initializing a continuous thermal energy management control loop within a controller disposed in the motor vehicle; calculating a quantity of stored energy in a thermal management system equipped to the motor vehicle including calculating a quantity of thermal energy stored in each of a plurality of dissimilar thermal fluid loops within the thermal management system; calculating a quantity of thermal energy waste in the thermal management system, wherein the quantity of thermal energy waste is a sum of excess thermal energy in each component of the thermal management system; determining if thermal energy is needed within a component of the thermal management system; selectively generating thermal energy; selectively transporting thermal energy to the component of the thermal management system; determining a thermal storage capacity of the thermal management system; determining if a thermal energy deficit exists within the thermal management system, wherein the thermal energy deficit is a quantity of thermal energy required by the thermal management system subtracted from the sum of the stored energy and the thermal energy waste; selectively directing a flow of a thermal energy carrying liquid to a thermal energy reservoir, and wherein each of the plurality of dissimilar thermal fluid loops exchanges thermal energy with another of the plurality of dissimilar thermal fluid loops through a heat exchange device, wherein the plurality of dissimilar thermal fluid loops comprises at least: a refrigerant loop, a coolant loop, and a drive unit oil loop, and wherein the refrigerant loop exchanges thermal energy with the coolant loop via a chiller, and wherein the drive unit oil loop exchanges thermal energy with the coolant loop via a transmission oil cooler; and selectively and precisely regulating a temperature of coolant passing through a radiator of the coolant loop by utilizing an airflow management device to selectively and variably prevent a flow of ambient air through the radiator, wherein calculating a quantity of stored energy in a thermal management system further comprises: calculating a quantity of thermal energy stored in a battery as a measure of a heat capacity of the battery multiplied by a temperature of the battery, subtracted from a temperature of coolant in the coolant loop; and calculating a quantity of thermal energy stored in the drive unit as a measure of a heat capacity of the drive unit multiplied by a temperature of oil in the drive unit oil loop, subtracted from the temperature of the coolant in the coolant loop, and wherein determining if thermal energy is needed further comprises: determining an optimal amount of regenerative braking energy such that thermal energy generated by the regenerative braking system is transferred by coolant in the coolant loop from the regenerative braking system to other thermal fluid loops and other components of the thermal management system. 2. The method of claim 1 wherein the chiller includes at least two passageways physically separated from one another, wherein a first passageway through the chiller carries coolant of the coolant loop, and a second passageway carries refrigerant as part of the refrigerant loop, and wherein the transmission oil cooler includes at least two passageways physically separated from one another, wherein a first passageway through the transmission oil cooler carries coolant of the coolant loop, and a second passageway through the transmission oil cooler carries oil of the drive unit oil loop. 3. The method of claim 1 wherein each of the plurality of dissimilar thermal fluid loops comprises different thermal management components carrying different fluids. 4. The method of claim 1 further comprising selectively operating a condenser, wherein selectively operating a condenser further comprises continuously operating the condenser, monitoring a condenser efficiency, and preventing condenser icing by exchanging thermal energy between dissimilar thermal fluid loops. 5. The method of claim 1 wherein determining if thermal energy is needed further comprises determining if a passenger compartment ambient temperature change has been requested. 6. The method of claim 1 wherein determining if thermal energy is needed further comprises determining an optimal operating temperature for a motor vehicle battery. 7. The method of claim 1 wherein determining if thermal energy is needed further comprises determining an optimal operating temperature for a motor vehicle drive unit, wherein the drive unit includes a motor. 8. The method of claim 1 wherein determining if thermal energy is needed further comprises determining an optimal amount of electrical energy to be drawn from an electrical grid when the motor vehicle is plugged into the electrical grid and charging. 9. The method of claim 1 wherein selectively generating thermal energy further comprises commanding at least one component in at least one of the dissimilar thermal fluid loops to generate a predetermined quantity of thermal energy; and wherein selectively directing a flow of a thermal energy carrying fluid further comprises selectively rejecting thermal energy to an atmosphere surrounding the motor vehicle. 10. The method of claim 1 wherein determining if a thermal energy deficit exists further comprises determining if a quantity of stored thermal energy is below a predetermined threshold thermal energy storage value. 11. A method for continuously managing thermal energy in a motor vehicle comprises: initializing a continuous thermal energy management control loop within a controller disposed in the motor vehicle; calculating a quantity of stored energy in a plurality of dissimilar thermal fluid loops within a thermal management system equipped to the motor vehicle including calculating a quantity of thermal energy stored in each of a plurality of dissimilar thermal fluid loops within the thermal management system, each of the dissimilar thermal fluid loops having different components and carrying a different fluid; calculating a quantity of thermal energy waste in the thermal management system, wherein the quantity of thermal energy waste is a sum of excess thermal energy in each component of the thermal management system; determining if thermal energy is needed within a component of the thermal management system; selectively commanding at least one component in at least one of the dissimilar thermal fluid loops to generate a predetermined amount of thermal energy; selectively transporting thermal energy to the component of the thermal management system; determining a thermal storage capacity of the thermal management system; determining if a thermal energy deficit exists within the thermal management system, wherein the thermal energy deficit is a quantity of thermal energy required by the thermal management system subtracted from the sum of the stored energy and the thermal energy waste; selectively directing a flow of a thermal energy carrying fluid to a thermal energy reservoir; selectively directing a flow of the thermal energy carrying fluid to a heat exchange device in at least one of the dissimilar thermal loops, wherein the heat exchange device is exposed to an atmosphere surrounding the motor vehicle, and wherein each of the plurality of dissimilar thermal fluid loops exchanges thermal energy with another of the plurality of dissimilar thermal fluid loops through a heat exchange device, wherein the plurality of dissimilar thermal fluid loops comprises at least: a refrigerant loop, a coolant loop, and a drive unit oil loop, and wherein the r