| name | neurokit2 |
| description | Comprehensive biosignal processing toolkit for analyzing physiological data including ECG, EEG, EDA, RSP, PPG, EMG, and EOG signals. Use this skill when processing cardiovascular signals, brain activity, electrodermal responses, respiratory patterns, muscle activity, or eye movements. Applicable for heart rate variability analysis, event-related potentials, complexity measures, autonomic nervous system assessment, psychophysiology research, and multi-modal physiological signal integration. |
| license | MIT license |
| metadata | {"skill-author":"K-Dense Inc."} |
NeuroKit2
Overview
NeuroKit2 is a comprehensive Python toolkit for processing and analyzing physiological signals (biosignals). Use this skill to process cardiovascular, neural, autonomic, respiratory, and muscular signals for psychophysiology research, clinical applications, and human-computer interaction studies.
When to Use This Skill
Apply this skill when working with:
- Cardiac signals: ECG, PPG, heart rate variability (HRV), pulse analysis
- Brain signals: EEG frequency bands, microstates, complexity, source localization
- Autonomic signals: Electrodermal activity (EDA/GSR), skin conductance responses (SCR)
- Respiratory signals: Breathing rate, respiratory variability (RRV), volume per time
- Muscular signals: EMG amplitude, muscle activation detection
- Eye tracking: EOG, blink detection and analysis
- Multi-modal integration: Processing multiple physiological signals simultaneously
- Complexity analysis: Entropy measures, fractal dimensions, nonlinear dynamics
Core Capabilities
1. Cardiac Signal Processing (ECG/PPG)
Process electrocardiogram and photoplethysmography signals for cardiovascular analysis. See references/ecg_cardiac.md for detailed workflows.
Primary workflows:
- ECG processing pipeline: cleaning → R-peak detection → delineation → quality assessment
- HRV analysis across time, frequency, and nonlinear domains
- PPG pulse analysis and quality assessment
- ECG-derived respiration extraction
Key functions:
import neurokit2 as nk
signals, info = nk.ecg_process(ecg_signal, sampling_rate=1000)
analysis = nk.ecg_analyze(signals, sampling_rate=1000)
hrv = nk.hrv(peaks, sampling_rate=1000)
2. Heart Rate Variability Analysis
Compute comprehensive HRV metrics from cardiac signals. See references/hrv.md for all indices and domain-specific analysis.
Supported domains:
- Time domain: SDNN, RMSSD, pNN50, SDSD, and derived metrics
- Frequency domain: ULF, VLF, LF, HF, VHF power and ratios
- Nonlinear domain: Poincaré plot (SD1/SD2), entropy measures, fractal dimensions
- Specialized: Respiratory sinus arrhythmia (RSA), recurrence quantification analysis (RQA)
Key functions:
hrv_indices = nk.hrv(peaks, sampling_rate=1000)
hrv_time = nk.hrv_time(peaks)
hrv_freq = nk.hrv_frequency(peaks, sampling_rate=1000)
hrv_nonlinear = nk.hrv_nonlinear(peaks, sampling_rate=1000)
hrv_rsa = nk.hrv_rsa(peaks, rsp_signal, sampling_rate=1000)
3. Brain Signal Analysis (EEG)
Analyze electroencephalography signals for frequency power, complexity, and microstate patterns. See references/eeg.md for detailed workflows and MNE integration.
Primary capabilities:
- Frequency band power analysis (Delta, Theta, Alpha, Beta, Gamma)
- Channel quality assessment and re-referencing
- Source localization (sLORETA, MNE)
- Microstate segmentation and transition dynamics
- Global field power and dissimilarity measures
Key functions:
power = nk.eeg_power(eeg_data, sampling_rate=250, channels=['Fz', 'Cz', 'Pz'])
microstates = nk.microstates_segment(eeg_data, n_microstates=4, method='kmod')
static = nk.microstates_static(microstates)
dynamic = nk.microstates_dynamic(microstates)
4. Electrodermal Activity (EDA)
Process skin conductance signals for autonomic nervous system assessment. See references/eda.md for detailed workflows.
Primary workflows:
- Signal decomposition into tonic and phasic components
- Skin conductance response (SCR) detection and analysis
- Sympathetic nervous system index calculation
- Autocorrelation and changepoint detection
Key functions:
signals, info = nk.eda_process(eda_signal, sampling_rate=100)
analysis = nk.eda_analyze(signals, sampling_rate=100)
sympathetic = nk.eda_sympathetic(signals, sampling_rate=100)
5. Respiratory Signal Processing (RSP)
Analyze breathing patterns and respiratory variability. See references/rsp.md for detailed workflows.
Primary capabilities:
- Respiratory rate calculation and variability analysis
- Breathing amplitude and symmetry assessment
- Respiratory volume per time (fMRI applications)
- Respiratory amplitude variability (RAV)
Key functions:
signals, info = nk.rsp_process(rsp_signal, sampling_rate=100)
rrv = nk.rsp_rrv(signals, sampling_rate=100)
rvt = nk.rsp_rvt(signals, sampling_rate=100)
6. Electromyography (EMG)
Process muscle activity signals for activation detection and amplitude analysis. See references/emg.md for workflows.
Key functions:
signals, info = nk.emg_process(emg_signal, sampling_rate=1000)
activation = nk.emg_activation(signals, sampling_rate=1000, method='threshold')
7. Electrooculography (EOG)
Analyze eye movement and blink patterns. See references/eog.md for workflows.
Key functions:
signals, info = nk.eog_process(eog_signal, sampling_rate=500)
features = nk.eog_features(signals, sampling_rate=500)
8. General Signal Processing
Apply filtering, decomposition, and transformation operations to any signal. See references/signal_processing.md for comprehensive utilities.
Key operations:
- Filtering (lowpass, highpass, bandpass, bandstop)
- Decomposition (EMD, SSA, wavelet)
- Peak detection and correction
- Power spectral density estimation
- Signal interpolation and resampling
- Autocorrelation and synchrony analysis
Key functions:
filtered = nk.signal_filter(signal, sampling_rate=1000, lowcut=0.5, highcut=40)
peaks = nk.signal_findpeaks(signal)
psd = nk.signal_psd(signal, sampling_rate=1000)
9. Complexity and Entropy Analysis
Compute nonlinear dynamics, fractal dimensions, and information-theoretic measures. See references/complexity.md for all available metrics.
Available measures:
- Entropy: Shannon, approximate, sample, permutation, spectral, fuzzy, multiscale
- Fractal dimensions: Katz, Higuchi, Petrosian, Sevcik, correlation dimension
- Nonlinear dynamics: Lyapunov exponents, Lempel-Ziv complexity, recurrence quantification
- DFA: Detrended fluctuation analysis, multifractal DFA
- Information theory: Fisher information, mutual information
Key functions:
complexity_indices = nk.complexity(signal, sampling_rate=1000)
apen = nk.entropy_approximate(signal)
dfa = nk.fractal_dfa(signal)
lyap = nk.complexity_lyapunov(signal, sampling_rate=1000)
10. Event-Related Analysis
Create epochs around stimulus events and analyze physiological responses. See references/epochs_events.md for workflows.
Primary capabilities:
- Epoch creation from event markers
- Event-related averaging and visualization
- Baseline correction options
- Grand average computation with confidence intervals
Key functions:
events = nk.events_find(trigger_signal, threshold=0.5)
epochs = nk.epochs_create(signals, events, sampling_rate=1000,
epochs_start=-0.5, epochs_end=2.0)
grand_average = nk.epochs_average(epochs)
11. Multi-Signal Integration
Process multiple physiological signals simultaneously with unified output. See references/bio_module.md for integration workflows.
Key functions:
bio_signals, bio_info = nk.bio_process(
ecg=ecg_signal,
rsp=rsp_signal,
eda=eda_signal,
emg=emg_signal,
sampling_rate=1000
)
bio_analysis = nk.bio_analyze(bio_signals, sampling_rate=1000)
Analysis Modes
NeuroKit2 automatically selects between two analysis modes based on data duration:
Event-related analysis (< 10 seconds):
- Analyzes stimulus-locked responses
- Epoch-based segmentation
- Suitable for experimental paradigms with discrete trials
Interval-related analysis (≥ 10 seconds):
- Characterizes physiological patterns over extended periods
- Resting state or continuous activities
- Suitable for baseline measurements and long-term monitoring
Most *_analyze() functions automatically choose the appropriate mode.
Installation
uv pip install neurokit2
For development version:
uv pip install https://github.com/neuropsychology/NeuroKit/zipball/dev
Common Workflows
Quick Start: ECG Analysis
import neurokit2 as nk
ecg = nk.ecg_simulate(duration=60, sampling_rate=1000)
signals, info = nk.ecg_process(ecg, sampling_rate=1000)
hrv = nk.hrv(info['ECG_R_Peaks'], sampling_rate=1000)
nk.ecg_plot(signals, info)
Multi-Modal Analysis
bio_signals, bio_info = nk.bio_process(
ecg=ecg_signal,
rsp=rsp_signal,
eda=eda_signal,
sampling_rate=1000
)
results = nk.bio_analyze(bio_signals, sampling_rate=1000)
Event-Related Potential
events = nk.events_find(trigger_channel, threshold=0.5)
epochs = nk.epochs_create(processed_signals, events,
sampling_rate=1000,
epochs_start=-0.5, epochs_end=2.0)
ecg_epochs = nk.ecg_eventrelated(epochs)
eda_epochs = nk.eda_eventrelated(epochs)
References
This skill includes comprehensive reference documentation organized by signal type and analysis method:
- ecg_cardiac.md: ECG/PPG processing, R-peak detection, delineation, quality assessment
- hrv.md: Heart rate variability indices across all domains
- eeg.md: EEG analysis, frequency bands, microstates, source localization
- eda.md: Electrodermal activity processing and SCR analysis
- rsp.md: Respiratory signal processing and variability
- ppg.md: Photoplethysmography signal analysis
- emg.md: Electromyography processing and activation detection
- eog.md: Electrooculography and blink analysis
- signal_processing.md: General signal utilities and transformations
- complexity.md: Entropy, fractal, and nonlinear measures
- epochs_events.md: Event-related analysis and epoch creation
- bio_module.md: Multi-signal integration workflows
Load specific reference files as needed using the Read tool to access detailed function documentation and parameters.
Additional Resources
