Nonlinear model predictive control for chemical looping process

What is claimed is: 1. A controller system for optimizing operation of a chemical looping plant having a loop A and a loop B, each of the loop A and the Loop B having respective seal pot valves, and a respective pressure control device, the system comprising: a non-linear model predictive controller (“NMPC”) adapted to: receive a plurality of user setpoints, pressure measurements, solid mass flows and solid levels of both loops A and B; create respective optimum signals for the respective seal pot valves of loop A; create respective optimum signals for the respective pressure control device of loop A; create respective optimum signals for the respective seal pot valves of loop B; create respective optimum signals for the respective pressure control device of loop B provide to loop A the respective optimum signals for the respective seal pot valves of loop A, and respective optimum signals for the respective pressure control device of loop A, to control the respective seal pot valves and the respective pressure control device of loop A; provide to loop B the respective optimum signals for the respective seal pot valves of loop B, and respective optimum signals for the respective pressure control device of loop B, to control the respective seal pot valves and respective pressure control device of loop B; an observer adapted to: receive pressure and differential pressure measurements from loops A and B; calculate solids mass flow and solids levels in loops A and B, and provide the calculated solids mass flow and solids levels of loops A and B to the NMPC. 2. The controller system of claim 1 , wherein the user setpoints are differential pressures of loop A, and differential pressures of loop B, and a ratio of differential pressure in loop A to the sum of the differential pressures of both loops A and B. 3. A controller system for optimizing operation of a chemical looping plant having a loop A and a loop B, each of the loop A and the loop B having a respective seal pot valve, and a respective pressure control device, the system comprising: a non-linear model predictive controller (“NMPC”) adapted to: receive a plurality of user setpoints, pressure measurements, solid mass flows and solid levels of both loops A and B; create respective optimum signals for the respective seal pot valve of loop A; create respective optimum signals for the respective pressure control device of loop A; create respective optimum signals for the respective seal pot valve of loop B; create respective optimum signals for the respective pressure control device of loop B; provide to loop A the respective optimum signals for the respective seal pot valve of loop A, and respective optimum signals for the respective pressure control device of loop A, to control the respective seal pot valve and the respective pressure control device of loop A; provide to loop B the respective optimum signals for the respective seal pot valve of loop B, and respective optimum signals for the respective pressure control device of loop B, to control the respective seal pot valve and respective pressure control device of loop B; an observer adapted to: receive pressure and differential pressure measurements from loops A and B; calculate solids mass flows of loops A and B, and provide the calculated solids mass flows of loops A and B to the NMPC. 4. The controller system of claim 3 , wherein the user setpoints are the differential pressures of loop A and of loop B, and a ratio of differential pressure in loop A to the total pressure difference of both loops A and B. 5. A Neural Network (NN) controller system for optimizing operation of a chemical looping plant having a loop A and a loop B, each of the loop A and the loop B having a respective seal pot valve, and a respective pressure control device, the system comprising: a neural network non-linear model predictive controller (“NN NMPC”) adapted to: receive a differential pressure signal of loop A and a differential pressure signal of loop B; create respective optimum signals for the seal pot valve of loop A; create respective optimum signals for the seal pot valve of loop B; create respective optimum signals for the respective pressure control device of loop A; create respective optimum signals for the respective pressure control device of loop B; provide to loop A the respective optimum signals for the respective seal pot valve of loop A, and the respective optimum signals for the respective pressure control device of loop A, to control the respective seal pot valve and respective pressure control device of loop A; provide to loop B the respective optimum signals for the respective seal pot valve of loop B, and the respective optimum signals for the respective pressure control device of loop A, to control the respective seal pot valve and respective pressure control device of loop B; a difference device adapted to receive a pressure signal from loop A, and a pressure signal from loop B, and to create a pressure difference signal; a PID 2 coupled to the difference device to receive the pressure difference signal and to create a signal to run the respective pressure control device of loop B; a ratio device adapted to receive a respective differential pressure signal from each of loop A and from loop B, respectively, and to create a signal related to the ratio of the respective differential pressure signals received from loop A and loop B; a PID 1 coupled to the ratio device adapted to receive the signal related to the ratio of inputs and to create a signal for operating the respective seal pot valves of loop B; a load-based FF controller that creates a first signal that is provided to loop A, and a second signal that is provided to loop B; and wherein loop A provides the pressure signal, the respective differential pressure signal, and the differential pressure signal to the difference device, the ratio device, and the NN NMPC, respectively; and wherein loop B provides the pressure signal, the differential pressure signal, and the differential pressure signal to the difference device, the ratio device and the NN NMPC, respectively.