Robust fixed-sequence control method and appliance for exceptional temperature stability

What is claimed is: 1. A method for fixed-sequence control of a dual evaporator cooling system comprising the steps of: providing a cooling system having a compressor, a condenser, a condenser fan, first and second evaporator fans, and a valve operating in a recurring fixed-sequence cooling cycle wherein each recurring fixed-sequence cooling cycle comprises a first cooling cycle for cooling a first interior, a second cooling cycle for cooling a second interior, a pump-out cycle for returning a coolant to the condenser, and an idle cycle; providing a processor for regulating the operation of the compressor, the condenser fan, the first and second evaporator fans, and the valve wherein the processor establishes exceptions to the recurring fixed-sequence cooling cycle; monitoring a first actual temperature of the first interior; monitoring a second actual temperature of the second interior; selecting a predetermined first control temperature for the first interior; selecting a predetermined second control temperature for the second interior; and selecting a command input signal to supply to the compressor, the condenser fan, the first and second evaporator fans, and the valve during the recurring fixed-sequence cooling cycle based upon the first and second actual temperatures and the predetermined first and second control temperatures to initiate the established exceptions. 2. The method of claim 1 , further comprising the step of: comparing the first actual temperature to the predetermined first control temperature to determine a first temperature difference; comparing the first temperature difference to a set of predetermined first temperature difference ranges to determine a first priority value; comparing the second actual temperature to the predetermined second control temperature to determine a second temperature difference; comparing the second temperature difference to a set of predetermined second temperature difference ranges to determine a second priority value; and selecting a command input signal based upon the first and second priority values. 3. The method of claim 2 , wherein the step of selecting a command input signal based upon the first and second priority values, includes the addition of first and second hysteresis values to the first and second temperature differences, respectively. 4. The method of claim 2 , wherein the step of establishing exceptions to the recurring fixed-sequence cooling cycle further comprises the steps of: selecting a command input signal to initiate a pull-down exception to provide alternating cooling between the first and second interiors outside of the recurring fixed-sequence cooling cycle when the first priority value reaches a predetermined upper priority limit and the second priority value reaches the predetermined upper priority limit; selecting a command input signal to initiate a second interior cooling exception during a current first interior cooing mode to provide cooling to the second interior outside of the recurring fixed-sequence cooling cycle when the pull-down exception has not been initiated and when: a. the second priority value reaches the predetermined upper priority limit; or b. the second priority value exceeds the first priority value by a predetermined comparative parameter limit; and selecting a command input signal to initiate a first interior cooling exception during a current second interior cooing mode to provide cooling to the first interior outside of the fixed-sequence cooling cycle when the pull-down exception has not been initiated and when the first priority value exceeds the second priority value by the predetermined comparative parameter limit. 5. The method of claim 4 , wherein the step of establishing exceptions to the recurring fixed-sequence cooling cycle further comprises the step of: selecting a command input signal to initiate an idle exception wherein the compressor and the condenser fan are turned off outside of the recurring fixed-sequence cooling cycle when: a. the first priority value is falls below a predetermined first priority baseline and the second priority value falls below a predetermined second priority baseline; or b. a second interior cooling cycle is delayed by a current defrost cycle that began before the second interior cooling cycle was to be initiated, wherein the initiation of the second interior cooling cycle will begin after the completion of the current defrost cycle. 6. The method of claim 5 , wherein the recurring fixed-sequence cooling cycle includes a first fixed-sequence, wherein the method further comprises: selecting a command input signal to initiate a second interior cooling exception to provide cooling to the second interior outside of the recurring fixed-sequence cooling cycle after the current pump-out cycle is complete and when: a. the second priority value reaches the predetermined upper priority limit; or b. the second priority value exceeds the first priority value by a predetermined comparative parameter limit. 7. A method for fixed-sequence control of a dual evaporator cooling system comprising the steps of: providing a cooling system having a compressor, a condenser, a condenser fan, first and second evaporator fans, and a valve operating in any one of a plurality a recurring fixed-sequence cooling cycles wherein each of the plurality of recurring fixed-sequence cooling cycles comprises a first cooling cycle for cooling a first interior, a second cooling cycle for cooling a second interior, a pump-out cycle for returning a coolant to the condenser, and an idle cycle; providing a processor for regulating the operation of the compressor, the condenser fan, the first and second evaporator fans and the valve to establish exceptions to each of the plurality of recurring fixed-sequence cooling cycles; monitoring a first actual temperature of the first interior; monitoring a second actual temperature of the second interior; selecting a predetermined first control temperature for the first interior; selecting a predetermined second control temperature for the second interior; and selecting a command input signal to supply to the compressor, the condenser fan, the first and second evaporator fans, and the valve during each of the plurality of recurring fixed-sequence cooling cycles based upon the first and second actual temperatures and the predetermined first and second control temperatures to initiate the established exceptions. 8. The method of claim 7 , further comprising the steps of: comparing the first actual temperature to the predetermined first control temperature to determine a first temperature difference; comparing the first temperature difference to a set of predetermined first temperature difference ranges to determine a first priority value; comparing the second actual temperature to the predetermined second control temperature to determine a second temperature difference; comparing the second temperature difference to a set of predetermined second temperature difference ranges to determine a second priority value; and selecting a command input signal based upon the first and second priority values. 9. The method of claim 8 , wherein the step of selecting a command input signal based upon the first and second priority values, includes the addition of first and second hysteresis values to the first and second temperature differences, respectively. 10. The method of claim 8 , wherein the step of establishing exceptions to any one of the plurality of recurring fixed-sequence cooling cycles further comprises the steps of: selecting a command input signal to initiate a pull-down exception to provide alternating cooling between the first an