Allocation of energy production changes to meet demand changes

The invention claimed is: 1. A method of controlling a utility plant having multiple devices which consume power and provide energy, the method comprising: receiving a forecast of building energy demand; receiving a forecast of factors influencing the operation of the utility plant; operating an optimizer in a scheduling mode to determine which devices should be on and to provide control actions to specify a set point for each running device so that the operation is economically optimal and no constraint is violated; operating the optimizer such that the optimizer takes into account a cost or penalty for starting up and shutting down the multiple devices between neighboring time intervals; and operating the optimizer in a control mode to distribute energy demand between the devices based on efficiency and response times of the devices to minimize purchased energy cost; wherein the method is performed for each of multiple scheduling intervals constituting an operation schedule for a scheduling time horizon; and wherein device set points are determined to minimize cost (C) in accordance with ∑ k = 0 K ⁢ C k ⁡ ( t ) ⟶ min ,  where k is the index of purchased and sold energy in the a t-th control interval. 2. The method of claim 1 wherein the multiple factors that influence operation of the utility plant include weather conditions, building temperature set point and building occupancy. 3. A computer implemented method of optimizing a utility plant having multiple devices to convert input energy into output energy for a building, the method comprising: dividing a utility plant scheduling interval into several control intervals and for each control interval: obtain a difference between a desired and a measured in-building condition controlled by a device from the utility plant; obtain current values of multiple factors that influence operation of the utility plant; determine a power demand of the building expected to decrease the difference; find set points for the multiple devices that satisfy the power demand, take into account response times of the devices and their capacities, and optimize utility plant operation costs; and for each control interval where no such set points are found: remove an exact match requirement for meeting the power demand; modify an optimization objective by adding a member representing weighted energy imbalance which is a difference between a desired demand and the energy available; and accept the result as the best possible step in the direction of eliminating the difference between the desired and measured in-building condition; determining if the desired indoor air conditions cannot be achieved in a specified number of intervals; and changing a configuration of devices operating in the utility plant by: receiving a forecast of building energy demand; receiving a forecast of factors influencing the operation of the utility plant; and operating the optimizer in a scheduling mode to determine which devices should be on and to provide control actions to specify a set point for each running device so that the operation is economically optimal and no constraint is violated as a function of energy cost. 4. The computer implemented method of claim 3 wherein the set points for the multiple devices are selected as a function of cost. 5. The computer implemented method of claim 3 wherein the set points for the multiple devices are set to minimize the difference between a desired and a measured in-building condition and modified to optimize cost in later intervals. 6. The computer implemented method of claim 5 wherein the difference is minimized as a function of weighted difference between the desired and measured in-building condition. 7. The computer implemented method of claim 5 wherein the set points are changed on devices having faster response times to minimize the difference. 8. The computer implemented method of claim 5 wherein set points for more efficient devices are changed to optimize the cost in the later intervals. 9. The method of claim 3 wherein device set points are determined to minimize cost of energy from public resources (C) in accordance with ∑ k = 0 K ⁢ C k ⁡ ( t ) ⟶ min , where k is the index of purchased energy less earning from sold energy in the a t-th control interval. 10. The computer implemented method of claim 3 wherein the multiple factors that influence operation of the utility plant include ambient temperature. 11. The computer implemented method of claim 3 wherein the multiple factors that influence operation of the utility plant include purchased energy cost. 12. The computer implemented method of claim 3 wherein the control intervals are treated by the method as a series of independent self-contained optimizations. 13. A device comprising: a processor; input connections to receive energy demand, real time energy price data, and influencing condition information; and a memory device coupled to the processor and having a program stored thereon for execution by the processor to perform utility plant optimization by dividing a utility plant scheduling interval into several control intervals and for each control interval: obtaining a difference between a desired and a measured in-building condition controlled by a device from the utility plant; obtaining current values of multiple factors that influence operation of the utility plant; determining a power demand of the building expected to decrease the difference; finding set points for the multiple devices that satisfy the new power demand and take into account response times of the devices and their capacities; and for each control interval where no such set points are found, optimization further comprises: removing an exact match requirement for meeting the new output power demand; modifying an optimization objective by adding a member representing weighted energy imbalance which is a difference between a desired demand and the energy available; and accepting the result as the best possible step in the direction of eliminating the difference between the desired and measured in-building condition; determining if the desired indoor air conditions cannot be achieved in a specified number of intervals with a current configuration of multiple devices; and changing the configu