In addition to estimating model parameters, the toolbox algorithms also estimate variability of the model parameters that result from random disturbances in the output.
Understanding model variability helps you to understand how different your model parameters would be if you repeated the estimation using a different data set (with the same input sequence as the original data set) and the same model structure.
When validating your parametric models, check the uncertainty values. Large uncertainties in the parameters might be caused by high model orders, inadequate excitation, and poor signal-to-noise ratio in the data.
Uncertainty in the model is called model covariance.
When you estimate a model, the covariance matrix of the estimated
parameters is stored with the model. Use
fetch the covariance matrix. Use
fetch the list of parameters and their individual uncertainties that
have been computed using the covariance matrix. The covariance matrix
is used to compute all uncertainties in model output, Bode plots,
residual plots, and pole-zero plots.
Computing the covariance matrix is based on the assumption that the model structure gives the correct description of the system dynamics. For models that include a disturbance model H, a correct uncertainty estimate assumes that the model produces white residuals. To determine whether you can trust the estimated model uncertainty values, perform residual analysis tests on your model. For more details about residual analysis, see the topics on the Residual Analysis page. If your model passes residual analysis tests, there is a good chance that the true system lies within the confidence interval and any parameter uncertainties results from random disturbances in the output.
For output-error models, such as transfer function models, state-space
with K=0 and polynomial models of output-error form, with the noise
model H fixed to
1, the covariance
matrix computation does not assume white residuals. Instead, the covariance
is estimated based on the estimated color of the residual correlations.
This estimation of the noise color is also performed for state-space
models with K=
0, which is
equivalent to an output-error model.
You can view the following uncertainty information from linear and nonlinear grey-box models:
Uncertainties of estimated parameters.
present(model) at the prompt, where
the name of a linear or nonlinear model.
Confidence intervals on the linear model plots, including step-response, impulse-response, Bode, Nyquist, noise spectrum and pole-zero plots.
Confidence intervals are computed based on the variability in the model parameters. For information about displaying confidence intervals, see Definition of Confidence Interval for Specific Model Plots.
Covariance matrix of the estimated parameters in linear
models and nonlinear grey-box models using
Simulated output values for linear models with standard
sim command with output arguments,
where the second output argument is the estimated standard deviation
of each output value. For example, type
[ysim,ysimsd] = sim(model,data),
ysim is the simulated output,
the standard deviations on the simulated output, and
the simulation data.
Perform Monte-Carlo analysis using
rsample to generate a random sampling
of an identified model in a given confidence region. An array of identified
systems of the same structure as the input system is returned. The
parameters of the returned models are perturbed about their nominal
values in a way that is consistent with the parameter covariance.
Simulate the effect of parameter uncertainties on
a model's response using
You can display the confidence interval on the following plot types:
|Plot Type||Confidence Interval Corresponds to the Range of ...||More Information on Displaying Confidence Interval|
|Simulated and Predicted Output||Output values with a specific probability of being the actual output of the system.||Model Output Plots|
|Residuals||Residual values with a specific probability of being statistically insignificant for the system.||Residuals Plots|
|Impulse and Step||Response values with a specific probability of being the actual response of the system.||Impulse and Step Plots|
|Frequency Response||Response values with a specific probability of being the actual response of the system.||Frequency Response Plots|
|Noise Spectrum||Power-spectrum values with a specific probability of being the actual noise spectrum of the system.||Noise Spectrum Plots|
|Poles and Zeros||Pole or zero values with a specific probability of being the actual pole or zero of the system.||Pole-Zero Plots|