Method of estimating catalyst temperature of a multi-displacement internal combustion engine

What is claimed is: 1. A method of estimating temperature of a catalyst associated with a cylinder bank of a multi-displacement internal combustion engine having multiple cylinder banks associated with multiple catalysts, comprising: setting a temperature estimate of the catalysts associated with the multiple cylinder banks substantially equal to a base model temperature; determining deactivation of a cylinder bank of the multiple cylinder banks; identifying a catalyst cooldown correction for the catalyst associated with the deactivated cylinder bank from a catalyst cooldown model including time elapsed since deactivation of the cylinder bank; and applying the catalyst cooldown correction to the temperature estimate of the catalyst associated with the deactivated cylinder bank to update the temperature estimate of the catalyst, wherein determining deactivation of the cylinder bank includes identifying that the cylinder bank has been deactivated while a different cylinder bank is still operating in accordance with multi-displacement operation. 2. The method of claim 1 wherein the catalyst cooldown model includes a lookup table. 3. The method of claim 1 , further comprising: identifying an ambient temperature adjustment for the catalyst cooldown correction from an ambient temperature model including outside ambient temperature; and applying the ambient temperature adjustment to the catalyst cooldown correction to update the temperature estimate of the catalyst. 4. The method of claim 3 wherein the ambient temperature model includes a lookup table. 5. The method of claim 3 wherein the outside ambient temperature is sensed using a temperature sensor. 6. The method of claim 1 , further comprising: determining reactivation of the deactivated cylinder bank; comparing the temperature estimate of the catalyst to the base model temperature for the catalyst; using the base model temperature if the temperature estimate is greater than the base model temperature; and if the temperature estimate is less than the base model temperature, identifying a catalyst warmup correction for the catalyst from a catalyst warmup model including cumulative heat associated with the cylinder bank, and applying the catalyst warmup correction to the temperature estimate of the catalyst to update the temperature estimate of the catalyst. 7. The method of claim 6 , further comprising: incrementing a multi-displacement mode timer after determining deactivation of the cylinder bank; and resetting the multi-displacement mode timer after determining reactivation of the cylinder bank. 8. The method of claim 6 , further comprising: identifying a mass flow adjustment for the catalyst warmup correction from a mass flow model including mass flow associated with the reactivated cylinder bank; and applying the mass flow adjustment to the catalyst warmup correction to update the temperature estimate of the catalyst. 9. The method of claim 1 , further comprising incrementing a multi-displacement mode timer after determining deactivation of the cylinder bank. 10. A method of estimating temperature of a catalyst associated with a cylinder bank of a multi-displacement internal combustion engine having multiple cylinder banks associated with multiple catalysts, comprising: a) setting temperature estimates of the catalysts associated with the multiple cylinder banks substantially equal to a base model temperature; b) determining deactivation of a cylinder bank of the multiple cylinder banks; c) incrementing a multi-displacement mode timer; d) identifying a catalyst cooldown correction for the catalyst associated with the deactivated cylinder bank from a catalyst cooldown model including time elapsed since deactivation of the cylinder bank as determined from the incremented multi-displacement mode timer; e) applying the catalyst cooldown correction to the temperature estimate of the catalyst associated with the deactivated cylinder bank to update the temperature estimate of the catalyst; f) identifying an ambient temperature adjustment for the catalyst cooldown correction from an ambient temperature model including outside ambient temperature; g) applying the ambient temperature adjustment to the catalyst cooldown correction to update the temperature estimate of the catalyst; h) determining reactivation of the cylinder bank; i) resetting the multi-displacement mode timer; j) comparing the temperature estimate of the catalyst to the base model temperature for the catalyst; k) using the base model temperature if the temperature estimate is greater than the base model temperature; l) but if the temperature estimate is less than the base model temperature, l1) identifying a catalyst warmup correction for the catalyst associated with the reactivated cylinder bank from a catalyst warmup model including cumulative heat associated with the cylinder bank, and l2) applying the catalyst warmup correction to the temperature estimate of the catalyst to update the temperature estimate of the catalyst; m) identifying a mass flow adjustment for the catalyst warmup correction from a mass flow model including mass flow associated with the reactivated cylinder bank; n) applying the mass flow adjustment to the catalyst warmup correction to update the temperature estimate of the catalyst; and o) using the temperature estimate of the catalyst as an input variable to determine whether to conduct on-board diagnostics of an exhaust system oxygen sensor.