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Statistical Model Calibration and Validation

Statistical Model Calibration and Validation. C12. Overview. Grey box models and model calibration Data analysis and preprocessing Model parameter and structure estimation: linear-nonlinear static-dynamic Model validation. A Systematic Modelling Procedure. 1. 4. 7.

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Statistical Model Calibration and Validation

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  1. Statistical Model Calibration and Validation C12

  2. Overview • Grey box models and model calibration • Data analysis and preprocessing • Model parameter and structure estimation: • linear-nonlinear • static-dynamic • Model validation

  3. A Systematic Modelling Procedure 1 4 7 Model calibration & validation Problem definition Model construction 2 5 Controlling factors Model solution 3 6 Problem data Model verification

  4. Grey-box Models Process models • developed from first engineering principles (white box part) • part of their parameters and/or structure unknown (black box part) are called grey-box models

  5. Model CalibrationConceptual Problem Statement • Given: • grey-box model • calibration data (measured data) • measure of fit (loss function) • Estimate: the parameter values and/or structural elements

  6. Model CalibrationConceptual Steps of Solution • Analysis of model specification • Sampling of continuous time dynamic models • Data analysis and preprocessing • Model parameter and structure estimation • Evaluation of the quality of the estimate

  7. Sampling of Continuous Time Dynamic Models Equi-distant zero-order hold sampling Discrete time input signal: u : {u(k)=u(tk) | k=1,2,...} output signal: y : {y(k)=y(tk) | k=1,2,...}

  8. Sampling of Continuous Time Dynamic Models Model parameters (1st order approximation) Continuous time model equations: model parameters: (A ,B,C,D) Discrete time model equations: model parameters:  = I+Ah ,  = Bh ( ,,C,D)

  9. gross errors outliers trends Data visualization Outlier tests Trends, steady state tests Gross error detection Data Analysis and Preprocessing -Data Screening- Check measured data for: Methods to be used include:

  10. Data Screening - Visualization Gross errors

  11. Data Screening - Visualization Trends and jumps

  12. Experimental Design for Parameter Estimation Static models • number of measurements • test point spacing • test point sequencing Dynamic models (in addition) • sampling time selection • excitation PseudoRandomBinarySignal (PRBS)

  13. Model Parameter and Structure Estimation • Conceptual problem statement • Least Squares parameter estimation - estimation procedure - properties of the estimate - linear and nonlinear models • Parameter estimation for static models • Parameter estimation for dynamic models

  14. Problem Statement of Model Parameter Estimation Given: • System model: • Set of measured data: • Loss function: Compute: an estimate such that

  15. Problem Statement of Model Structure Estimation Given: • System model: (not parametrized) • Set of measured data: • Loss function: Compute: an estimate such that + “candidate structures” in

  16. Least Squares (LS) Parameter Estimation Given: • System model: linear in p, single y(M) • Measured data: • Loss function: Compute: an estimate such that

  17. Properties of LS Parameter Estimation Estimation: with Gaussian measurement errors: • unbiased: • covariance matrix:

  18. Assessing the Fit Residuals are independent and • residual tests • correlation coefficient measures

  19. Confidence Regions and Intervals Individual confidence intervals:

  20. LS Parameter Estimation for Nonlinear Models Solution • Transformation into linear form • Solution by (numerical) optimization • Properties has lost its nice properties - non-normally distributed - confidence region and confidence intervals are not symmetric - unbiased

  21. Confidence Interval for Nonlinear Parameter Estimation Sum-of-squares as a function of a parameter

  22. Static Models Linear in Parameters General form Examples

  23. Identification: Model Parameter and Structure Estimation of Dynamic Models Properties of the estimation problem variables (y and x) are time dependent ordered x : present and past inputs and outputs measurement errors on both y and x Steps 1. sampling continuous time models 2. estimation

  24. Parameter Estimation of Dynamic Models Linear in Parameters General form of the input-output model LS parameter estimation with

  25. Parameter Estimation of Nonlinear Dynamic Models

  26. Statistical Model Validation via Parameter EstimationConceptual Problem Statement • Given: • a calibrated model • validation data (measured data) • measure of fit (loss function) • Question: Is the calibrated model “good enough” for the purpose?(Does it reproduce the data well?)

  27. A Systematic Modelling Procedure 1 4 7 Model calibration & validation Problem definition Model construction 2 5 Controlling factors Model solution 3 6 Problem data Model verification

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