Wavelet Time-Frequency Analyzer
Visualize scalogram of signals
The Wavelet Time-Frequency Analyzer app is an interactive tool for visualizing scalograms of real- and complex-valued 1-D signals. The scalogram is the absolute value of the continuous wavelet transform (CWT) plotted as a function of time and frequency. Frequency is plotted on a logarithmic scale. With the app, you can:
Access all 1-D signals in your MATLAB® workspace
Import multiple signals simultaneously
Adjust default parameters and visualize scalograms using
Select desired analytic wavelet
Adjust analytic Morse wavelet symmetry and time-bandwidth parameters
Export the CWT to your workspace
Recreate the scalogram in your workspace by generating a MATLAB script
Import multiple signals
For more information, see Using Wavelet Time-Frequency Analyzer App.
Open the Wavelet Time-Frequency Analyzer App
MATLAB Toolstrip: On the Apps tab, under Signal Processing and Communications, click the app icon.
MATLAB command prompt: Enter
Visualize Scalograms Using Default Settings
Load three 1-D signals into the MATLAB® workspace: an electrocardiogram signal, a hyperbolic chirp signal, and the NPG2006 dataset.
load wecg load hyperbolchirp load npg2006
Extract the complex-valued signal from the
npg2006 structure array.
npgdata = npg2006.cx; whos
Name Size Bytes Class Attributes hyperbolchirp 2048x1 33759 timetable npg2006 1x1 37184 struct npgdata 1117x1 17872 double complex wecg 2048x1 16384 double
Open Wavelet Time-Frequency Analyzer and click Import Signals. A window appears listing all the workspace variables the app can process.
Select all the signals and click Import. After a brief, one-time initialization, the Signals pane is populated with the names of the imported signals, along with their types. In the case of
hyperbolchirp, the name of the timetable variable containing the signal is appended to the name of the timetable:
hyperbolchirp_hchirp. The app displays the scalogram of the highlighted signal. The scalogram is obtained using the
cwt function with default settings. The cone of influence showing where edge effects become significant is also plotted. Gray regions outside the dashed white lines delineate regions where edge effects are significant. By default, frequencies are in cycles/sample.
The ECG signal is real valued. In the Signals pane, select the complex-valued signal
npgdata. The positive and negative components of the scalogram are displayed.
hyperbolchirp_hchirp. Because the timetable contains temporal information, the scalogram is plotted as a function of frequency in hertz and uses the row times of the timetable as the basis for the time axis. The disabled Sample Rate field displays the sampling rate as determined from the row times.
Adjust Morse Wavelet Parameters
Load the hyperbolic chirp signal.
Open Wavelet Time-Frequency Analyzer and import the signal into the app. To access the parameter settings, click the Scalogram tab. By default, the app displays the scalogram obtained using the analytic Morse (3, 60) wavelet and the
cwt function with default settings.
You can reset the CWT parameters to their default values at any time by clicking Reset Parameters. Resetting the parameters enables the Compute Scalogram button.
To visualize the scalogram using the (1,5) Morse wavelet, set Time-Bandwidth Product to 5. In the status bar, text appears stating there are pending changes. The Compute Scalogram button is now enabled. If you instead first set Symmetry to 1, the app would automatically change that value because a symmetry value of 1 violates the constraint that the ratio of Time-Bandwidth Product to Symmetry should not exceed 40. For more information, see Tips.
Now set Symmetry to 1 and click Compute Scalogram. The app displays the scalogram obtained using the (1, 5) Morse wavelet.
To visualize the scalogram using the (6, 50) Morse wavelet, first set Time-Bandwidth Product to 50 and Symmetry to 6, then click Compute Scalogram.
Adjust Scalogram Frequency Axis Scale
Load a hyperbolic chirp signal into your workspace.
Open Wavelet Time-Frequency Analyzer and import the signal. To access the parameter settings, click the Scalogram tab. By default, the app displays the scalogram obtained using the Morse (3,60) wavelet and the
cwt function with default settings. Because the signal is a timetable, the scalogram is plotted as a function of frequency in hertz. The time axis is based on the row times of the timetable.
In the Scalogram tab, adjust the default settings. Specify the Morse (5,20) wavelet. Visualize the scalogram using 26 voices per octave and periodic boundary extension. The frequencies are plotted on a logarithmic scale.
To adjust the frequency axis scale in the scalogram, first reproduce the wavelet analysis in your workspace.
Generate a script that recreates the scalogram in your workspace. From the Export ▼ menu, select
Generate MATLAB Script. An untitled script opens in your MATLAB® Editor. To include the boundary line of the cone of influence in the plot, add a third output argument,
coi, to the
cwt function call in the script. Save and execute the script. The variables
frequency contain the scalogram and frequency vector, respectively.
%Parameters waveletParameters = [5,20]; voicesPerOctave = 26; extendSignal = false; %Compute cwt %Run the function call below without output arguments to plot the results [waveletTransform,frequency,coi] = cwt(hyperbolchirp,... WaveletParameters = waveletParameters,... VoicesPerOctave = voicesPerOctave,... ExtendSignal = extendSignal); scalogram = abs(waveletTransform);
In order to plot the scalogram using the correct time axis, extract the vector of row times,
Time, from the
dataTimes = hyperbolchirp.Time;
Adjust Frequency Axis — Linear Scale
pcolor function to plot the scalogram. Include the cone of influence boundary. Frequency is plotted on a linear scale.
pcolor(dataTimes,frequency,scalogram) shading flat title("Scalogram") xlabel("Time (s)") ylabel("Frequency (Hz)") hold on plot(dataTimes,coi,"w--",LineWidth=2) hold off colorbar
Adjust Frequency Axis — Logarithmic Scale
To plot frequency on a logarithmic scale, get the handle to the current axes and set
AX = gca; set(AX,YScale="log")
In MATLAB, logarithmic axes are in powers of 10 (decades). By default, MATLAB places frequency ticks at 1, 10, and 100 because they are the powers of 10 between the minimum and maximum frequencies. To add more frequency axis ticks, obtain the minimum and maximum frequencies in
frequency. Create a logarithmically spaced set of frequencies between the minimum and maximum frequencies. Note that
cwt returns frequencies ordered from high to low.
minf = frequency(end); maxf = frequency(1); numfreq = 10; freq = logspace(log10(minf),log10(maxf),numfreq);
Replace the frequency axis ticks and labels with the new frequencies.
AX.YTickLabelMode = "auto"; AX.YTick = freq;
In the CWT, frequencies are computed in powers of two. Create the frequency ticks and tick labels in powers of two.
freq = 2.^(round(log2(minf)):round(log2(maxf))); AX.YTickLabelMode = "auto"; AX.YTick = freq;
Wavelet — Analytic wavelet
Morse (default) |
Analytic wavelet used to compute the CWT. Valid options are
specify the Morse, Morlet (Gabor), and bump wavelet, respectively.
Time-Bandwidth Product — Time-bandwidth product of the Morse wavelet
60 (default) | scalar greater than or equal to the Symmetry value
Specify the time-bandwidth product of the Morse wavelet as a scalar greater than or equal to the Symmetry value. The ratio of the Time-Bandwidth Product value to the Symmetry value cannot exceed 40.
The values of Time-Bandwidth Product and
Symmetry correspond to the
name-value argument of
Example: Setting Time-Bandwidth Product to 40 and
Symmetry value to 5 is equivalent to setting the
WaveletParameters name-value argument
Symmetry — Symmetry parameter of the Morse wavelet
3 (default) | scalar greater than or equal to
Specify the symmetry parameter of the Morse wavelet as a scalar greater than or equal to 1. The ratio of the Time-Bandwidth Product value to the Symmetry value cannot exceed 40.
The values of Symmetry and Time-Bandwidth
Product correspond to the
name-value argument of
Voices Per Octave — Number of voices per octave
10 (default) | integer between 1 and 48
Specify the number of voices per octave to use for the CWT as an integer from 1 to 48. The CWT scales are discretized using the specified number of voices per octave. The energy spread of the wavelet in frequency and time automatically determines the minimum and maximum scales.
waveletTimeFrequencyAnalyzer opens the Wavelet Time-Frequency
Analyzer app. Once the app initializes, import a signal for analysis by clicking
waveletTimeFrequencyAnalyzer( opens the
Wavelet Time-Frequency Analyzer app and imports, generates, and plots the
cwt with default settings.
sig is a variable in the workspace.
sig can be:
A real- or complex-valued vector.
A single-variable regularly sampled timetable.
Single or double precision.
sig must have at least four samples.
By default, the app plots the scalogram as a function of frequency in cycles/sample and uses sample index as the basis of the time axis. If the signal is a timetable, then the app plots the scalogram as a function of frequency in hertz and uses the row times of the timetable as the basis for the time axis.
The MATLAB script you generate to create the scalogram in your workspace uses the name of the selected signal in the Signals pane. The script will throw an error if the variable does not exist in the MATLAB workspace. If an error occurs, either replace the variable name in the script with the name of the original signal or create the variable in your workspace.
You can run only one instance of the Wavelet Time-Frequency Analyzer app in a MATLAB session.
The Morse wavelet parameters, Time-Bandwidth Product and Symmetry, must satisfy three constraints:
Symmetry, or gamma, must be greater than or equal to 1.
Time-Bandwidth Product must be greater than or equal to Symmetry.
The ratio of Time-Bandwidth Product to Symmetry cannot exceed 40.
To prevent attempts to visualize a scalogram using invalid settings, the app validates any parameter you change. If you enter a value that violates a constraint, the app automatically replaces it with a valid value. The new value might not be the desired value. To avoid unexpected results, you should ensure any value you enter always results in a valid setting. For more information, see the example Adjust Morse Wavelet Parameters.
Introduced in R2022a
- Wavelet Signal Analyzer | Signal Multiresolution Analyzer | Signal Analyzer (Signal Processing Toolbox)