Control system for managing steam turbine rotor stress and method of use

What is claimed is: 1. A control system for a power plant, said control system comprising: a temperature sensor configured to measure a surface temperature of a steam turbine rotor, the surface temperature a function of exhaust gasses from a heat source used to heat steam to a target steam temperature; and a controller coupled to said temperature sensor, said controller configured to: compute the target steam temperature using an inverse process model for steam turbine rotor stress dynamics that uses a reference steam turbine rotor stress and a feedback steam turbine rotor stress; compute a steam turbine rotor stress based on a measured surface temperature of the steam turbine rotor; compute an estimated steam turbine rotor stress using a process model for the steam turbine rotor stress dynamics, and based on the target steam temperature; and compute the feedback steam turbine rotor stress based on the measured steam turbine rotor stress and the estimated steam turbine rotor stress. 2. The control system in accordance with claim 1 , wherein the heat source comprises a gas turbine engine. 3. The control system in accordance with claim 1 , wherein said temperature sensor is configured to measure a steam, turbine shell temperature from which the surface temperature of the steam turbine rotor is determinable. 4. The control system in accordance with claim 1 , wherein said controller is further configured to compute the feedback steam turbine rotor stress as a difference between the measured steam turbine rotor stress and the estimated steam turbine rotor stress. 5. The control system in accordance with claim 4 , wherein said controller is further configured to compute the target steam temperature based on a difference of the reference steam turbine rotor stress and the feedback steam turbine rotor stress. 6. The control system in accordance with claim 1 , wherein said controller is further configured to low-pass filter the reference steam turbine rotor stress. 7. The control system in accordance with claim 1 , wherein said controller is further configured, using the inverse process model, to compute the target steam temperature based on an estimated surface temperature of the steam turbine rotor and a target temperature differential between the target steam temperature and the measured surface temperature of the steam turbine rotor. 8. The control system in accordance with claim 1 , wherein said controller is further configured to compute an exhaust gas temperature based on the target steam temperature and a heat exchange model for heat exchange from the exhaust gasses to the steam. 9. A power plant, comprising: a gas turbine engine configured to rotate under a gas turbine load and expel exhaust gasses at an exhaust gas temperature, the exhaust gasses configured to heat steam to a target steam temperature; a steam turbine into which the steam is admitted at the target steam temperature and a steam flow rate, said steam turbine configured to rotate an electrical generator; a temperature sensor configured to measure a stem turbine rotor surface temperature; and a controller configured to: compute the target steam temperature using an inverse process model for steam turbine rotor stress dynamics, and based on a reference steam turbine rotor stress and a feedback steam turbine rotor stress; compute a steam turbine rotor stress based on a measured surface temperature of the steam turbine rotor; compute an estimated steam turbine rotor stress using a process model for the steam turbine rotor stress dynamics the target steam temperature; and compute the feedback steam turbine rotor stress based on the measured steam turbine rotor stress and the estimated steam turbine rotor stress. 10. The power plant in accordance with claim 9 , wherein said controller is further configured to compute the measured steam turbine rotor stress based on variations in steam flow and loading of the gas turbine engine. 11. The power plant in accordance with claim 10 , wherein said controller is further configured to compute the feedback steam turbine rotor stress as a difference of the measured steam turbine rotor stress and the estimated steam turbine rotor stress. 12. The power plant in accordance with claim 10 , wherein said controller is further configured to compute the estimated steam turbine rotor stress based on a steam mass flow and the target steam temperature. 13. The power plant in accordance with claim 12 , wherein said controller is further configured to compute the estimated steam turbine rotor stress based on: a convection model for computing convection from the steam to a rotor surface of said steam turbine; a conduction model for computing conduction from said rotor surface to a bulk of said steam turbine based on an estimated steam turbine rotor surface temperature; and a stress computation based on a difference of the estimated steam turbine rotor surface temperature from said convection model and an estimated steam turbine rotor bulk temperature from said conduction model. 14. The power plant in accordance with claim 9 , wherein said controller is further configured to low-pass filter the reference steam turbine rotor stress.