Note: This page has been translated by MathWorks. Please click here

To view all translated materals including this page, select Japan from the country navigator on the bottom of this page.

To view all translated materals including this page, select Japan from the country navigator on the bottom of this page.

In this example, you use the RF Toolbox™ command-line interface to model the time-domain response of a parallel plate transmission line. You analyze the network in the frequency domain, compute and plot the time-domain response of the network, and export a Verilog-A model of the transmission line for use in system-level simulations.

Type the following command at the MATLAB

^{®}prompt to create a circuit (`rfckt`

) object to represent the transmission line, which is 0.1 meters long and 0.05 meters wide:tline = rfckt.parallelplate('LineLength',0.1,'Width',0.05);

Type the following set of commands at the MATLAB prompt to define the range of frequencies over which to analyze the transmission line and then run the analysis:

f = [1.0e9:1e7:2.9e9]; analyze(tline,f);

This part of the example illustrates how to perform the following tasks:

Type the following command at the MATLAB prompt to extract the computed S-parameter values and the corresponding frequency values for the transmission line:

`[S_Params, Freq] = extract(tline,'S_Parameters');`

Type the following command at the MATLAB prompt to compute the transfer function from the frequency response data using the

`s2tf`

function:TrFunc = s2tf(S_Params);

In this part of the example, you fit a rational function model
to the transfer function. The toolbox stores the fitting results in
an `rfmodel`

object. You use the RF Toolbox `freqresp`

method
to validate the fit of the rational function model.

Type the following command at the MATLAB prompt to fit a rational function to the computed data and store the result in an

`rfmodel`

object:RationalFunc = rationalfit(Freq,TrFunc)

RationalFunc = rfmodel.rational with properties: A: [7x1 double] C: [7x1 double] D: 0 Delay: 0 Name: 'Rational Function'

Type the following command at the MATLAB prompt to compute the frequency response of the fitted model data:

[fresp,freq] = freqresp(RationalFunc,Freq);

Type the following set of commands at the MATLAB prompt to plot the amplitude of the frequency response of the fitted model data and that of the computed data:

figure plot(freq/1e9,20*log10(abs(fresp)),freq/1e9,20*log10(abs(TrFunc))) xlabel('Frequency, GHz') ylabel('Amplitude, dB') legend('Fitted Model Data','Computed Data')

### Note

The amplitude of the model data is very close to the amplitude of the computed data. You can control the tradeoff between model accuracy and model complexity by specifying the optional tolerance argument,

`tol`

, to the`rationalfit`

function, as described in Represent a Circuit Object with a Model Object.Type the following set of commands at the MATLAB prompt to plot the phase angle of the frequency response of the fitted model data and that of the computed data:

figure plot(freq/1e9,unwrap(angle(fresp)),... freq/1e9,unwrap(angle(TrFunc))) xlabel('Frequency, GHz') ylabel('Phase Angle, radians') legend('Fitted Data','Computed Data')

### Note

The phase angle of the model data is very close to the phase angle of the computed data.

In this part of the example, you compute and plot the time-domain response of the transmission line.

Type the following set of commands at the MATLAB prompt to create a random input signal and compute the time response,

`tresp`

, of the fitted model data to the input signal:`SampleTime = 1e-12; NumberOfSamples = 1e4; OverSamplingFactor = 25; InputTime = double((1:NumberOfSamples)')*SampleTime; InputSignal = ... sign(randn(1, ceil(NumberOfSamples/OverSamplingFactor))); InputSignal = repmat(InputSignal, [OverSamplingFactor, 1]); InputSignal = InputSignal(:); [tresp,t] = timeresp(RationalFunc,InputSignal,SampleTime);`

Type the following set of commands at the MATLAB prompt to plot the time response of the fitted model data:

figure plot(t,tresp) xlabel('Time (seconds)') ylabel('Response to Random Input Signal')

In this part of the example, you export a Verilog-A model of the transmission line. You can use this model in other simulation tools for detailed time-domain analysis and system simulations.

The following code illustrates how to use the `writeva`

method
to write a Verilog-A module for `RationalFunc`

to
the file `tline.va`

. The module has one input, `tline_in`

,
and one output, `tline_out`

. The method returns a `status`

of `True`

,
if the operation is successful, and `False`

if it
is unsuccessful.

status = writeva(RationalFunc,'tline','tline_in','tline_out')

For more information on the `writeva`

method
and its arguments, see the `writeva`

reference
page. For more information on Verilog-A models, see Export a Verilog-A Model.

Was this topic helpful?