AI for Signals and Images
Wavelet techniques are effective for obtaining sparse, compressive data representations or features, which you can use in machine learning and deep learning workflows. Wavelet Toolbox™ supports deployment of multiscale feature extraction algorithms through MATLAB® Coder™ and GPU Coder™ for a number of targets. To take advantage of the performance benefits offered by a modern graphics processing unit (GPU), certain Wavelet Toolbox functions can perform operations on a GPU. These functions provide GPU acceleration for your workflows. Wavelet Toolbox also provides functionality to perform signal labeling.
Highlighted Topics
Categories
- Working with Signals
Multiresolution analysis, joint time-frequency scattering, wavelet time scattering, continuous wavelet transform, nondecimated discrete wavelet transform, Wigner-Ville distribution, mel spectrogram
- Working with Images
Wavelet image scattering, 2-D continuous wavelet transform, shearlets, stationary wavelet transform
- GPU Acceleration
Feature extraction on GPUs for machine learning and deep learning workflows
- Hardware Deployment
C/C++ code generation, GPU code generation, Raspberry Pi®, NVIDIA® Jetson®
Related Information
Featured Examples
Acoustic Scene Classification with Wavelet Scattering
Use wavelet scattering and joint time-frequency scattering with a support vector machine to classify urban environments by sound.
Anomaly Detection Using Autoencoder and Wavelets
Learn how wavelet features can be used to detect arc faults in a DC system.
Anomaly Detection Using Convolutional Autoencoder with Wavelet Scattering Sequences
Detect anomalies in acoustic data using wavelet scattering with the
deepSignalAnomalyDetector object.
Classify Time Series Using Wavelet Analysis and Deep Learning
Classify electrocardiogram data using deep learning and the continuous wavelet transform.
Detect Anomalies Using Wavelet Scattering with Autoencoders
Learn how to develop an alert system for predictive maintenance using wavelet scattering and deep learning.
Human Health Monitoring Using Continuous Wave Radar and Deep Learning
Reconstruct electrocardiogram signals using a bidirectional long short-term memory network and wavelet multiresolution analysis.
Musical Instrument Classification with Joint Time-Frequency Scattering
Classify musical instruments using joint time-frequency features paired with a 3-D convolutional network.
Signal Recovery with Differentiable Scalograms and Spectrograms
Use differentiable time-frequency transforms and gradient descent to recover a time-domain signal without the need for phase information.
Time-Frequency Convolutional Network for EEG Data Classification
Classify electroencephalographic (EEG) time series from persons with and without epilepsy.
Time-Frequency Feature Embedding with Deep Metric Learning
Construct wavelet-based feature embeddings to classify EEG signals from persons with and without epilepsy.
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