System and Method for Controlling Operations of Air-Conditioning System

We claim: 1 . A method for controlling an operation of an air-conditioning system generating airflow in a conditioned environment, comprising: determining values of the airflow measured in the conditioned environment during the operation of the air-conditioning system; updating a model of airflow dynamics connecting values of flow and temperature of air conditioned during the operation of the air-conditioning system, wherein the updating iteratively reduces an error between values of the airflow determined according to the model and the measured values of the airflow; modeling the airflow using the updated model; and controlling the operation of the air-conditioning system using the modeled airflow, wherein steps of the method are performed using at least one processor of a controller. 2 . The method of claim 1 , wherein the updating minimizes a cost function of the error subject to stability constraints. 3 . The method of claim 1 , wherein the model includes a reduced order model having a number of parameters less than a physical model of the airflow according to a Boussinesq equation, wherein the Boussinesq equation is a partial differential equation (PDE), and wherein the reduced order model is an ordinary differential equation (ODE). 4 . The method of claim 3 , wherein the model includes a stability parameter representing a difference between the reduced order model and the physical model, and wherein the updating comprises: updating only the stability parameter of the model in response to detecting the error. 5 . The method of claim 4 , wherein the model is {dot over (x)} r =b+Ax r +x r T Bx r +F ( K,x ), wherein b, A, B are constants, x is a vector of states of the airflow, x r is a vector of the states with a reduced dimension r, F is the stability parameter represented as a function of its arguments, and K is a vector of stability coefficients ensuring a stability of the model of the airflow dynamics. 6 . The method of claim 5 , wherein the updating includes minimizing a cost function of the error subject to stability constraints according to Min K  ( t )  Q  ( e ) K  ( t ) ∈ Stability   constraints , wherein the error includes e=x ( t )− x m ( t ), wherein x(t) are the values of the airflow determined according to the model at a time t, and x m (t) are the values of the airflow measured during the operation at the time t, wherein the cost function includes Q ( e )=∫ t 0 t f e ( t ) T We ( t ) dt,W> 0, wherein W is a positive definite weight matrix, and t 0 , t f are an initial value and a final value of a given time interval of the operation, and T is a transpose operator. 7 . The method of claim 6 , wherein the stability constraints for the vector of stability coefficients are Kε{KεR r , s.t. eig({tilde over ( A )})<0}, wherein eig (.) stands for eigenvalues of the matrix (.), and the matrix à is Ã=A+x m ( t ) T ( B T +B )− K ( t ). 8 . The method of claim 3 , further comprising: determining the reduced order model using a model reduction method projecting an exact solution of the Boussinesq equation with infinite dimensions into an approximate solution of finite dimension; and adding the stability parameter to the reduced order model to form the model of the airflow dynamics. 9 . The method of claim 1 , further comprising: determining the error between a subset of states of the airflow measured by a set of sensors placed in an environment conditioned by the air-conditioning system and a corresponding subset of states of the airflow determined using the model. 10 . The method of claim 9 , wherein the model includes a reduced order model according to an ordinary differential equation (ODE) having a number of parameters less than a physical model of the airflow according to a partial differential equation (PDE), wherein the sensor in the set of sensors are arranged to maximize an observability gramian of the ODE or the PDE. 11 . The method of claim 1 , further comprising: determining a subset of states of the airflow measured by a set of sensors placed in the conditioned environment; estimating a set of states of the airflow from the subset of states to produce an estimated set of states of the airflow; modeling the airflow using the model to produce a modeled set of states of the airflow; and determining the error between the estimated set of states and the modeled set of states. 12 . The method of claim 3 , further comprising: reconstructing modes of the physical model from the values of the airflow measured during the operation using a compressive sensing; and selecting the reduced order model associated with dominant modes of the reconstructed modes of the physical model. 13 . The method of claim 1 , wherein the controlling comprises: updating at least one control input for at least one component of the air-conditioning system to optimize a metric of performance determined using the model. 14 . A system for controlling an operation of an air-conditioning system generating airflow in a conditioned environment, comprising: a set of sensors for measuring values of the airflow in the conditioned environment; and a controller for controlling the operation based on the airflow, wherein the controller comprises: a memory storing a model of airflow dynamics connecting values of flow and temperature of air conditioned during the operation of the air-conditioning system, and a processor for updating iteratively the model of airflow dynamics to reduce an error between values of the airflow determined according to the model and the values of the airflow measured during the operation. 15 . The system of claim 14 , wherein the controlling changes a vent angle of the air-conditioning system. 16 . The system of claim 14 , wherein the model includes a reduced order model according to an ordinary differential equation (ODE) having a number of parameters less than a physical model of the airflow according to a partial differential equation (PDE), wherein sensor in the set of sensors are arranged to maximize an observability gramian of the ODE or the PDE. 17 . The system of claim 14 , wherein the model includes a reduced order model having a number of parameters less than a physical model of the airflow, and a stability parameter representing a difference between the reduced order model and the physical model, and wherein the processor updating only the stability parameter of the model in response to detecting the error by m