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Open-source Python package for exploring, visualizing, and analyzing human neurophysiological data including EEG, MEG, sEEG, and ECoG.
Codex 또는 Claude로 설치 이 Prompt를 복사해 Codex, Claude 또는 다른 어시스턴트에 붙여 넣으면 Skill 페이지를 검토하고 설치를 진행할 수 있습니다.
SOC 직업 분류 기준
| name | mne |
| description | Open-source Python package for exploring, visualizing, and analyzing human neurophysiological data including EEG, MEG, sEEG, and ECoG. |
| version | 1.6 |
| license | BSD-3-Clause |
MNE provides sophisticated tools for filtering brain signals, epoching data, and performing source localization (mapping signals back to brain anatomy).
The standard pipeline: continuous raw data → segmented epochs → averaged evoked responses.
Sensor space: signals at electrodes. Source space: signals reconstructed at brain locations.
Brain signals are analyzed in frequency bands (delta, theta, alpha, beta, gamma).
import mne
import numpy as np
# 1. Load data
raw = mne.io.read_raw_fif("sample_audvis_raw.fif")
# Or: raw = mne.io.read_raw_edf("eeg.edf")
# 2. Filter and cleaning
raw.filter(l_freq=1, h_freq=40) # Bandpass filter
raw.notch_filter(freqs=[50, 100]) # Remove power line noise
# 3. Find events and create Epochs
events = mne.find_events(raw)
epochs = mne.Epochs(raw, events, event_id={'stimulus': 1}, tmin=-0.2, tmax=0.5)
epochs.average().plot() # Plot Evoked potential
# 4. Frequency analysis
epochs.compute_psd().plot()
raw.plot() to visually inspect for artifacts.# Compute forward solution and inverse
fwd = mne.make_forward_solution(raw.info, trans, src, bem)
inv = mne.minimum_norm.make_inverse_operator(raw.info, fwd, cov)
stc = mne.minimum_norm.apply_inverse(evoked, inv)
stc.plot()
from mne.connectivity import spectral_connectivity
# Compute connectivity between channels
con, freqs, times, n_epochs, n_tapers = spectral_connectivity(
epochs, method='coh', mode='multitaper')
MNE is the gold standard for neurophysiological data analysis, enabling researchers to extract meaningful insights from the complex signals of the human brain.
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