aeon
This skill should be used for time series machine learning tasks including classification, regression, clustering, forecasting, anomaly detection, segmentation, and similarity search. Use when working with temporal data, sequential patterns, or time-indexed observations requiring specialized algorithms beyond standard ML approaches. Particularly suited for univariate and multivariate time series analysis with scikit-learn compatible APIs.
What this skill does
# Aeon Time Series Machine Learning
## Overview
Aeon is a scikit-learn compatible Python toolkit for time series machine learning. It provides state-of-the-art algorithms for classification, regression, clustering, forecasting, anomaly detection, segmentation, and similarity search.
## When to Use This Skill
Apply this skill when:
- Classifying or predicting from time series data
- Detecting anomalies or change points in temporal sequences
- Clustering similar time series patterns
- Forecasting future values
- Finding repeated patterns (motifs) or unusual subsequences (discords)
- Comparing time series with specialized distance metrics
- Extracting features from temporal data
## Installation
```bash
uv pip install aeon
```
## Core Capabilities
### 1. Time Series Classification
Categorize time series into predefined classes. See `references/classification.md` for complete algorithm catalog.
**Quick Start:**
```python
from aeon.classification.convolution_based import RocketClassifier
from aeon.datasets import load_classification
# Load data
X_train, y_train = load_classification("GunPoint", split="train")
X_test, y_test = load_classification("GunPoint", split="test")
# Train classifier
clf = RocketClassifier(n_kernels=10000)
clf.fit(X_train, y_train)
accuracy = clf.score(X_test, y_test)
```
**Algorithm Selection:**
- **Speed + Performance**: `MiniRocketClassifier`, `Arsenal`
- **Maximum Accuracy**: `HIVECOTEV2`, `InceptionTimeClassifier`
- **Interpretability**: `ShapeletTransformClassifier`, `Catch22Classifier`
- **Small Datasets**: `KNeighborsTimeSeriesClassifier` with DTW distance
### 2. Time Series Regression
Predict continuous values from time series. See `references/regression.md` for algorithms.
**Quick Start:**
```python
from aeon.regression.convolution_based import RocketRegressor
from aeon.datasets import load_regression
X_train, y_train = load_regression("Covid3Month", split="train")
X_test, y_test = load_regression("Covid3Month", split="test")
reg = RocketRegressor()
reg.fit(X_train, y_train)
predictions = reg.predict(X_test)
```
### 3. Time Series Clustering
Group similar time series without labels. See `references/clustering.md` for methods.
**Quick Start:**
```python
from aeon.clustering import TimeSeriesKMeans
clusterer = TimeSeriesKMeans(
n_clusters=3,
distance="dtw",
averaging_method="ba"
)
labels = clusterer.fit_predict(X_train)
centers = clusterer.cluster_centers_
```
### 4. Forecasting
Predict future time series values. See `references/forecasting.md` for forecasters.
**Quick Start:**
```python
from aeon.forecasting.arima import ARIMA
forecaster = ARIMA(order=(1, 1, 1))
forecaster.fit(y_train)
y_pred = forecaster.predict(fh=[1, 2, 3, 4, 5])
```
### 5. Anomaly Detection
Identify unusual patterns or outliers. See `references/anomaly_detection.md` for detectors.
**Quick Start:**
```python
from aeon.anomaly_detection import STOMP
detector = STOMP(window_size=50)
anomaly_scores = detector.fit_predict(y)
# Higher scores indicate anomalies
threshold = np.percentile(anomaly_scores, 95)
anomalies = anomaly_scores > threshold
```
### 6. Segmentation
Partition time series into regions with change points. See `references/segmentation.md`.
**Quick Start:**
```python
from aeon.segmentation import ClaSPSegmenter
segmenter = ClaSPSegmenter()
change_points = segmenter.fit_predict(y)
```
### 7. Similarity Search
Find similar patterns within or across time series. See `references/similarity_search.md`.
**Quick Start:**
```python
from aeon.similarity_search import StompMotif
# Find recurring patterns
motif_finder = StompMotif(window_size=50, k=3)
motifs = motif_finder.fit_predict(y)
```
## Feature Extraction and Transformations
Transform time series for feature engineering. See `references/transformations.md`.
**ROCKET Features:**
```python
from aeon.transformations.collection.convolution_based import RocketTransformer
rocket = RocketTransformer()
X_features = rocket.fit_transform(X_train)
# Use features with any sklearn classifier
from sklearn.ensemble import RandomForestClassifier
clf = RandomForestClassifier()
clf.fit(X_features, y_train)
```
**Statistical Features:**
```python
from aeon.transformations.collection.feature_based import Catch22
catch22 = Catch22()
X_features = catch22.fit_transform(X_train)
```
**Preprocessing:**
```python
from aeon.transformations.collection import MinMaxScaler, Normalizer
scaler = Normalizer() # Z-normalization
X_normalized = scaler.fit_transform(X_train)
```
## Distance Metrics
Specialized temporal distance measures. See `references/distances.md` for complete catalog.
**Usage:**
```python
from aeon.distances import dtw_distance, dtw_pairwise_distance
# Single distance
distance = dtw_distance(x, y, window=0.1)
# Pairwise distances
distance_matrix = dtw_pairwise_distance(X_train)
# Use with classifiers
from aeon.classification.distance_based import KNeighborsTimeSeriesClassifier
clf = KNeighborsTimeSeriesClassifier(
n_neighbors=5,
distance="dtw",
distance_params={"window": 0.2}
)
```
**Available Distances:**
- **Elastic**: DTW, DDTW, WDTW, ERP, EDR, LCSS, TWE, MSM
- **Lock-step**: Euclidean, Manhattan, Minkowski
- **Shape-based**: Shape DTW, SBD
## Deep Learning Networks
Neural architectures for time series. See `references/networks.md`.
**Architectures:**
- Convolutional: `FCNClassifier`, `ResNetClassifier`, `InceptionTimeClassifier`
- Recurrent: `RecurrentNetwork`, `TCNNetwork`
- Autoencoders: `AEFCNClusterer`, `AEResNetClusterer`
**Usage:**
```python
from aeon.classification.deep_learning import InceptionTimeClassifier
clf = InceptionTimeClassifier(n_epochs=100, batch_size=32)
clf.fit(X_train, y_train)
predictions = clf.predict(X_test)
```
## Datasets and Benchmarking
Load standard benchmarks and evaluate performance. See `references/datasets_benchmarking.md`.
**Load Datasets:**
```python
from aeon.datasets import load_classification, load_regression
# Classification
X_train, y_train = load_classification("ArrowHead", split="train")
# Regression
X_train, y_train = load_regression("Covid3Month", split="train")
```
**Benchmarking:**
```python
from aeon.benchmarking import get_estimator_results
# Compare with published results
published = get_estimator_results("ROCKET", "GunPoint")
```
## Common Workflows
### Classification Pipeline
```python
from aeon.transformations.collection import Normalizer
from aeon.classification.convolution_based import RocketClassifier
from sklearn.pipeline import Pipeline
pipeline = Pipeline([
('normalize', Normalizer()),
('classify', RocketClassifier())
])
pipeline.fit(X_train, y_train)
accuracy = pipeline.score(X_test, y_test)
```
### Feature Extraction + Traditional ML
```python
from aeon.transformations.collection import RocketTransformer
from sklearn.ensemble import GradientBoostingClassifier
# Extract features
rocket = RocketTransformer()
X_train_features = rocket.fit_transform(X_train)
X_test_features = rocket.transform(X_test)
# Train traditional ML
clf = GradientBoostingClassifier()
clf.fit(X_train_features, y_train)
predictions = clf.predict(X_test_features)
```
### Anomaly Detection with Visualization
```python
from aeon.anomaly_detection import STOMP
import matplotlib.pyplot as plt
detector = STOMP(window_size=50)
scores = detector.fit_predict(y)
plt.figure(figsize=(15, 5))
plt.subplot(2, 1, 1)
plt.plot(y, label='Time Series')
plt.subplot(2, 1, 2)
plt.plot(scores, label='Anomaly Scores', color='red')
plt.axhline(np.percentile(scores, 95), color='k', linestyle='--')
plt.show()
```
## Best Practices
### Data Preparation
1. **Normalize**: Most algorithms benefit from z-normalization
```python
from aeon.transformations.collection import Normalizer
normalizer = Normalizer()
X_train = normalizer.fit_transform(X_train)
X_test = normalizer.transform(X_test)
```
2. **Handle Missing Values**: Impute before analysis
```python
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