| | --- |
| | language: |
| | - en |
| | --- |
| | Chaos Classifier: Logistic Map Regime Detection via 1D CNN |
| | This model classifies time series sequences generated by the logistic map into one of three dynamical regimes: |
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| | 0 β Stable (converges to a fixed point) |
| | 1 β Periodic (oscillates between repeating values) |
| | 2 β Chaotic (irregular, non-repeating behavior) |
| | The goal is to simulate financial market regimes using a controlled chaotic system and train a model to learn phase transitions directly from raw sequences. |
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| | Motivation |
| | Financial systems often exhibit regime shifts: stable growth, cyclical trends, and chaotic crashes. |
| | This model uses the logistic map as a proxy to simulate such transitions and demonstrates how a neural network can classify them. |
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| | Data Generation |
| | Sequences are generated from the logistic map equation: |
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| | [ x_{n+1} = r \cdot x_n \cdot (1 - x_n) ] |
| | |
| | Where: |
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| | xβ β (0.1, 0.9) is the initial condition |
| | r β [2.5, 4.0] controls behavior |
| | Label assignment: |
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| | r < 3.0 β Stable (label = 0) |
| | 3.0 β€ r < 3.57 β Periodic (label = 1) |
| | r β₯ 3.57 β Chaotic (label = 2) |
| | Model Architecture |
| | A 1D Convolutional Neural Network (CNN) was used: |
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| | Conv1D β BatchNorm β ReLU Γ 2 |
| | GlobalAvgPool1D |
| | Linear β Softmax (via CrossEntropyLoss) |
| | Advantages of 1D CNN: |
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| | Captures local temporal patterns |
| | Learns wave shapes and jitters |
| | Parameter-efficient vs. MLP |
| | Performance |
| | Trained on 500 synthetic sequences (length = 100), test accuracy reached: |
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| | 98β99% accuracy |
| | Smooth convergence |
| | Robust generalization |
| | Confusion matrix showed near-perfect stability detection and strong chaos/periodic separation |
| | Inference Example |
| | You can generate a prediction by passing an r value: |
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| | predict_regime(3.95, model, scaler, device) |
| | # Output: Predicted Regime: Chaotic (Class 2) |
