This program implements the cvxEDA algorithm for the analysis of electrodermal activity (EDA) using methods of convex optimisation, described in:
A. Greco, G. Valenza, A. Lanata, E. P. Scilingo, and L. Citi
“cvxEDA: a Convex Optimization Approach to Electrodermal Activity Processing”
IEEE Transactions on Biomedical Engineering, 2015
DOI: 10.1109/TBME.2015.2474131
It is based on a model which describes EDA as the sum of three terms:
- phasic component – transient increases reflecting sudomotor bursts;
- tonic component – slowly varying baseline activity;
- additive white‑Gaussian‑noise term – captures model prediction errors, measurement noise and artifacts.
The model is physiologically inspired and fully explains EDA through a rigorous methodology based on Bayesian statistics, convex optimisation and sparsity.
The algorithm was evaluated in three different experimental sessions (see paper) to test its robustness to noise, its ability to separate and identify stimulus inputs, and its capability of properly describing the activity of the autonomic nervous system in response to strong affective stimulation.
| Directory | Language | Description |
|---|---|---|
python/ | Python | cvxeda Python package |
matlab/ | MATLAB / Octave | cvxEDA.m and test scripts |
README_PYTHON.md | – | Python‑specific installation and usage |
README_MATLAB.md | – | MATLAB/Octave‑specific usage |
LICENSE.txt | – | GPL‑3.0 license text. |
- Python usage:
README_PYTHON.md - MATLAB/Octave usage:
README_MATLAB.md
The code is released under GPL‑3.0 (see LICENSE.txt).
If you use this program in support of published research, please cite the reference above. If you use this code in a software package, please explicitly inform the end users of this copyright notice and ask them to cite the reference above in their published research.
Project repository: https://github.com/lciti/cvxeda