Nonparametric impulse response estimation
data can be in the form of a
timetable, a comma-separated pair of numeric matrices, or an
iddata object. If
data is a timetable, the software assumes that the last
variable is the single output. You can select specific input and output channels to
use for estimation by specifying the channel names in the
The function uses persistence-of-excitation analysis on the input data to select the model order (number of nonzero impulse response coefficients).
Use nonparametric impulse response estimation to analyze input/output data for feedback effects, delays, and significant time constants.
uses additional model options specified by one or more name-value arguments. For
example, specify the input and output signal variable names using
sys = impulseest(___,
You can use this syntax with any of the previous input-argument combinations.
Identify Nonparametric Impulse Response Model from Data
Estimate a nonparametric impulse response model using data from a hair dryer. The input is the voltage applied to the heater and the output is the heater temperature. Use the first 500 samples for estimation.
Load the data and use the first 500 samples to estimate the model.
load dry2data dry2tt tte = dry2tt(1:500,:); sys = impulseest(tte);
tte is a timetable that contains time-domain data.
sys, the identified nonparametric impulse response model, is an
Analyze the impulse response of the identified model from time 0 to 1.
h = impulseplot(sys,1);
Determine the point at which a significant response to the impulse begins. First, display the region that bounds amplitudes that are not significantly different from zero. To do so, right-click the plot and select Characteristics > Confidence Region. For impulse response plots, by default, this selection displays a confidence region with a width of one standard deviation that is centered at zero, instead of one centered at the response values. You can modify these defaults by right-clicking the plot and selecting Properties > Options.
Alternatively, you can use the
The first response value that is significantly different than zero occurs at 0.24 seconds, or the third sample. This implies that the transport delay is three samples. To generate a model that imposes the three-sample delay, set the transport delay, which is the third argument, to 3. You must also set the second argument, the order
n, to its default value of
 as a placeholder.
sys1 = impulseest(tte,,3); h1 = impulseplot(sys1,1); showConfidence(h1);
The response is identically zero until 0.24 seconds.
Specify Order of FIR Model
Load the estimation data.
load sdata3 umat3 ymat3 Ts;
Estimate a 35th-order FIR model.
n = 35; sys = impulseest(umat3,ymat3,n);
You can confirm the model order of
sys by displaying the number of terms.
nsys = size(sys.num)
nsys = 1×2 1 35
 so that the function automatically determines
n. Display the model order.
n = ; sys1 = impulseest(umat3,ymat3,n); nsys1 = size(sys1.Numerator)
nsys1 = 1×2 1 70
The model order is 70. The default value for the order is
, so setting the order to
 is equivalent to omitting the specification.
Specify Transport Delay in FIR Model
Estimate an impulse response model with a transport delay of 3 samples.
If you know about the presence of delay in the input/output data in advance, use the delay value as a transport delay for impulse response estimation.
Generate data that contains a 3-sample input-to-output lag.
Create a random input signal. Construct an
idpoly model that includes three sample delays, which you implement by using three leading zeros in the B polynomial.
u = rand(100,1); A = [1 .1 .4]; B = [0 0 0 4 -2]; C = [1 1 .1]; sys = idpoly(A,B,C);
Simulate the model response
y to the noise signal, using the
AddNoise option and a sample time of 1 second. Encapsulate
y in an
opt = simOptions('AddNoise',true); y = sim(sys,u,opt); data = iddata(y,u,1);
Estimate and plot a 20th order model with no transport delay.
n = 20; model1 = impulseest(data,n); impulseplot(model1);
The plot shows that the impulse response includes nonzero samples during the 3-second delay period.
Estimate a model with a 3-sample transport delay.
nk = 3; model2 = impulseest(data,n,nk); impulseplot(model2)
The first three samples are identically zero.
Obtain Regularized Estimate of Impulse Response Model
Obtain regularized estimates of impulse response model using the regularizing kernel estimation option.
Estimate a model using regularization.
impulseest performs regularized estimates by default, using the tuned and correlated kernel (
load iddata3 z3; sys1 = impulseest(z3);
Estimate a model with no regularization.
opt = impulseestOptions('RegularizationKernel','none'); sys2 = impulseest(z3,opt);
Compare the impulse responses of both models.
h = impulseplot(sys2,sys1,70); legend('sys2','sys1')
As the plot shows, using regularization makes the response smoother.
Plot the confidence intervals.
The uncertainty in the computed response is reduced at larger lags for the model using regularization. Regularization decreases variance at the price of some bias. The tuning of the
'TC' regularization is such that the variance error dominates the overall error.
Use Regularized Impulse Response Model to Estimate State-Space Model
Load the estimation data.
load regularizationExampleData eData;
Recreate the transfer function model that was used for generating the estimation data (true system).
num = [0.02008 0.04017 0.02008]; den = [1 -1.561 0.6414]; Ts = 1; trueSys = idtf(num,den,Ts);
Obtain a regularized impulse response (FIR) model with an order of 70.
opt = impulseestOptions('RegularizationKernel','DC'); m0 = impulseest(eData,70,opt);
Convert the model into a state-space model and reduce the model order.
m1 = idss(m0); m1 = balred(m1,15);
Estimate a second state-space model directly from
eData by using regularized reduction of an ARX model.
m2 = ssregest(eData,15);
Compare the impulse responses of the true system and the estimated models.
The three model responses are similar.
Test Measured Data for Feedback Effects
Use the empirical impulse response to measured data to determine whether the data includes feedback effects. Feedback effects can be present when the impulse response includes statistically significant response values for negative time values.
Compute the noncausal impulse response using a fourth-order prewhitening filter and no regularization, automatic order selection, and negative lag.
load iddata3 z3; opt = impulseestOptions('pw',4,'RegularizationKernel','none'); sys = impulseest(z3,,'negative',opt);
sys is a noncausal model containing response values for negative time.
Analyze the impulse response of the identified model.
h = impulseplot(sys);
View the zero-response region at one standard deviation by right-clicking on the plot and selecting Characteristics > Confidence Region. Alternatively, you can use the
The large response value at
t=0 (zero lag) suggests that the data comes from a process containing feedthrough. That is, the input affects the output instantaneously. The large response value can also indicate direct feedback, such as proportional control without some delay so that y
(t) partly determines u
Other indications of feedback in the data are the significant response values such as those at -7 seconds and -9 seconds.
Compute Impulse Response on Frequency Response Data
Compute an impulse response model for frequency response data.
Load the frequency response data, which contains measured amplitude
AMP and phase
PHA for the frequency vector W.
Create the complex frequency response
zfr and encapsulate it in an
idfrd object that has a sample time of 0.1 seconds. Plot the data.
zfr = AMP.*exp(1i*PHA*pi/180); Ts = 0.1; data = idfrd(zfr,W,Ts);
Estimate an impulse response model from
data and plot the response.
sys = impulseest(data); impulseplot(sys)
Compare Identified Nonparametric and Parametric Models
Identify parametric and nonparametric models for a data set, and compare their step responses.
Estimate the impulse response model
sys1 (nonparametric) and state-space model
sys2 (parametric) using the estimation data set
load iddata1 z1; sys1 = impulseest(z1); sys2 = ssest(z1,4);
sys1 is a discrete-time identified transfer function model.
sys2 is a continuous-time identified state-space model.
Compare the step responses for
step(sys1,'b',sys2,'r'); legend('Impulse response model','State-space model');
data — Estimation data
timetable | numeric matrix pair |
data object | cell array of timetables | cell array of matrices
Uniformly sampled estimation data, specified as a timetable, a comma-separated matrix pair, or a data object, as the following sections describe.
data as a
timetable that uses a
regularly spaced time vector.
variables representing input and output channels.
For multiexperiment data, specify data as an Ne-by-1 cell array of timetables, where Ne is the number of experiments. The sample times of all the experiments must match.
When you use timetables for estimation, you can use all the variables
or specify a subset of channels to use. To select individual input and
output channels to use for estimation, use the
Comma-Separated Matrix Pair
data as a comma-separated pair of matrices u,y that contain uniformly sampled input and output time-domain signal values. Matrix-based data provides no sample-time information. The software assumes that the sample time is one second. Using matrix-based data for continuous-time systems is not recommended.
For SISO systems, specify u,y as column vectors with a length of Ns, where Ns is the number of samples.
For MIMO systems, specify u,y as a matrix pair with the following dimensions:
u — Ns-by-Nu, where Nu is the number of inputs
y — Ns-by-Ny, where Ny is the number of outputs
For multiexperiment data, specify u,y as a pair of 1-by-Ne cell arrays, where Ne is the number of experiments.
For time-domain estimation, specify
data as an
iddata object containing the input and output
For frequency-domain estimation, specify
one of the following:
Frequency response data (
iddataobject with properties specified as follows:
InputData— Fourier transform of the input signal
OutputData— Fourier transform of the output signal
For more information about working with estimation data types, see Data Domains and Data Types in System Identification Toolbox.
n — Order of FIR model
 (default) | positive integer | matrix
Order of the FIR model, specified as a positive integer,
, or a matrix.
datacontains a single input channel and output channel, or if you want to apply the same model order to all input/output pairs, specify
nas a positive integer.
datacontains Nu input channels and Ny output channels, and you want to specify individual model orders for the input/output pairs, specify
nas an Ny-by-Nu matrix of positive integers, such that N(i,j) represents the length of the impulse response from input j to output i.
If you want the function to determine the order automatically, specify
. The software uses persistence-of-excitation analysis on the input data to select the order.
sys = impulseest(data,70) estimates an impulse
response model of order 70.
nk — Transport delay
zero matrix (default) |
1 | scalar integer | matrix
Transport delay in the estimated impulse response, specified as a scalar
'negative', or an
matrix, where Ny is the number of
outputs and Nu is the number of
inputs. The impulse response (input
j to output
i) coefficients correspond to the time span
nk(i,j)*Ts : Ts : (n(ij)+nk(i,j)-1)*Ts.
If you know the value of the transport delay, specify
nkas a scalar integer or a matrix of scalar integers.
If you do not know the delay value, specify
0. Once you estimate the impulse response, you can determine the true delay from the nonsignificant impulse response values in the beginning portion of the response. For an example of finding a true delay, see Identify Nonparametric Impulse Response Model from Data.
To generate the impulse response coefficients for negative time values, which is useful for feedback analysis, use a negative integer. If you specify a negative value, the value must be the same across all output channels. You can also specify
'negative'to automatically pick negative lags for all input/output channels of the model. For an example of using negative time values, see Test Measured Data for Feedback Effects.
To create a system whose leading numerator coefficient is zero, specify
The function stores positive values of
nk greater than
1 in the
IODelay property of
negative values in the
opt — Estimation options
impulseestOptions option set
Estimation options, specified as an
impulseestOptions option set,
that specify the following:
Input and output data offsets
Advanced options such as structure
impulseestOptions to create the options
Specify optional pairs of arguments as
the argument name and
Value is the corresponding value.
Name-value arguments must appear after other arguments, but the order of the
pairs does not matter.
Before R2021a, use commas to separate each name and value, and enclose
Name in quotes.
sys = impulseest(data,'InputName',"u2")
InputName — Input channel names
string | character vector | string array | cell array of character vectors
Input channel names, specified as a string, character vector, string array, or cell array of character vectors.
If you are using a timetable for the data source, the names in
InputName must be a subset of the timetable variables.
sys = impulseest(tt,__,'InputName',["u1" "u2"]) selects
u2 as the input channels from
tt to use for the estimation.
OutputName — Output channel names
string | character vector | string array | cell array of character vectors
Output channel names, specified as a string, character vector, string array, or cell array of character vectors.
If you are using a timetable for the data source, the names in
OutputName must be a subset of the timetable variables.
sys = impulseest(tt,__,'OutputName',["y1" "y3"]) selects
y3 as the output channels
from the timetable
tt to use for the estimation.
sys — Estimated impulse response model
Estimated impulse response model, returned as an
idtf model that encapsulates
an FIR model.
Information about the estimation results and options used is stored in the
Report property of the model.
Report has the following fields.
Summary of the model status, which indicates whether the model was created by construction or obtained by estimation.
Estimation command used.
Quantitative assessment of the estimation, returned as a structure. See Loss Function and Model Quality Metrics for more information on these quality metrics. The structure has the following fields:
Estimated values of model parameters.
Option set used for estimation. If no custom
options were configured, this field is a set of default
State of the random number stream at the start of estimation. Empty,
Attributes of the data used for estimation, returned as a structure with the following fields.
For more information on using
Report, see Estimation Report.
A response value that corresponds to a negative time value and that is significantly different from zero in the impulse response of
sysindicates the presence of feedback in the data.
To view the region of responses that are not significantly different from zero (the zero-response region) in a plot, right-click on the plot and select Characteristics > Confidence Region. A patch depicting the zero-response region appears on the plot. The impulse response at any time value is significant only if it lies outside the zero-response region. The level of confidence in significance depends on the number of standard deviations specified in
showConfidenceor options in the property editor. The default value is 1 standard deviation, which gives 68% confidence. A common choice is 3 standard deviations, which gives 99.7% confidence.
Correlation analysis refers to methods that estimate the impulse response of a linear model, without specific assumptions about model orders.
The impulse response, g, is the system output when the input is an impulse signal. The output response to a general input, u(t), is the convolution with the impulse response. In continuous time:
In discrete time:
The values of g(k) are the discrete-time impulse response coefficients.
You can estimate the values from observed input/output data in several different ways.
impulseest estimates the first
n coefficients using the
least-squares method to obtain a finite impulse response (FIR) model
of order n.
impulseest provides several important options for the estimation:
Regularization — Regularize the least-squares estimate. With regularization, the algorithm forms an estimate of the prior decay and mutual correlation among g(k), and then merges this prior estimate with the current information about g from the observed data. This approach results in an estimate that has less variance but also some bias. You can choose one of several kernels to encode the prior estimate.
This option is essential because the model order
ncan often be quite large. In cases without regularization,
ncan be automatically decreased to secure a reasonable variance.
Specify the regularizing kernel using the
RegularizationKernelname-value argument of
Prewhitening — Prewhiten the input by applying an input-whitening filter of order
PWto the data. Use prewhitening when you are performing unregularized estimation. Using a prewhitening filter minimizes the effect of the neglected tail—
n—of the impulse response. To achieve prewhitening, the algorithm:
Defines a filter
PWthat whitens the input signal
1/A = A(u)e, where
Ais a polynomial and
eis white noise.
Filters the inputs and outputs with
uf = Au,
yf = Ay
Uses the filtered signals
Specify prewhitening using the
PWname-value pair argument of
Autoregressive Parameters — Complement the basic underlying FIR model by NA autoregressive parameters, making it an ARX model.
This option both gives better results for small n values and allows unbiased estimates when data are generated in closed loop.
impulseestsets NA to
5when t > 0 and sets NA to
0(no autoregressive component) when t < 0.
Noncausal effects — Include response to negative lags. Use this option if the estimation data includes output feedback:
where h(k) is the impulse response of the regulator and r is a setpoint or disturbance term. The algorithm handles the existence and character of such feedback h, and estimates h in the same way as g by simply trading places between y and u in the estimation call. Using
impulseestwith an indication of negative delays,
mi = impulseest(data,nk,nb), where
nk< 0, returns a model
miwith an impulse response
that has an alignment that corresponds to the lags . The algorithm achieves this alignment because the input delay (
InputDelay) of model
For a multi-input multi-output system, the impulse response g(k) is an ny-by-nu matrix, where ny is the number of outputs and nu is the number of inputs. The i–j element of the matrix g(k) describes the behavior of the ith output after an impulse in the jth input.
Version HistoryIntroduced in R2012a
R2022b: Time-domain estimation data is accepted in the form of timetables and matrices
Most estimation, validation, analysis, and utility functions now accept time-domain
input/output data in the form of a single timetable that contains both input and output data
or a pair of matrices that contain the input and output data separately. These functions
continue to accept
iddata objects as a data source as well, for
both time-domain and frequency-domain data.