Era Splitting - Invariant Learning for Decision Trees
Concepts de base
New splitting criteria improve OOS performance and reduce generalization gap in GBDT models.
Résumé
The article discusses the challenges of distributional shifts in machine learning problems and introduces new splitting criteria for decision trees to address out-of-distribution generalization. Traditional methods assume i.i.d. data, but real-life scenarios exhibit shifts over time or locations. The new criteria focus on linear models and neural networks, enhancing tree-based models like GBDTs. By incorporating era-wise information, the new criteria aim to optimize across disjoint eras rather than the entire dataset. Experimental results show improved performance in synthetic and real-world applications, such as financial markets and health domains.
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Era Splitting -- Invariant Learning for Decision Trees
Stats
Number of boosting iterations: 100, 2,000
Maximum number of leaves: 5, 32
Learning rate: 0.01, 1.0
Number of training eras: 3, 8
Total number of rows in dataset: Over 5 million
Citations
"The purpose of this field of research is to design ML procedures which allow models to ignore the spurious and learn the invariant signals in data."
"In Era Splitting, the split gain must be computed not once but M times per split."
"Both new splitting criteria improve OOS results on the Camelyon17 data set."
Questions plus approfondies
How can the added time complexity due to era splitting be mitigated effectively
To mitigate the added time complexity due to era splitting effectively, several strategies can be employed:
Feature Selection: Utilize feature selection techniques to reduce the number of features considered for splitting at each node. By focusing on the most relevant features, you can decrease computation time significantly.
Histogram Method Optimization: Optimize the histogram method parameters in modern software libraries to reduce the number of unique values considered for splitting. Setting this parameter appropriately can help speed up training without compromising model performance.
Parallel Processing: Implement parallel processing techniques to distribute computations across multiple cores or machines. This can lead to a significant reduction in training time by leveraging hardware resources efficiently.
Data Preprocessing: Streamline data preprocessing steps and ensure data is well-organized and cleaned before training begins. Efficient data handling practices can contribute to faster model training times.
Model Complexity Reduction: Consider simplifying the model architecture or reducing hyperparameters that may not significantly impact performance but contribute to increased computational load during training.
By implementing these strategies thoughtfully, it is possible to mitigate the time complexity associated with era splitting while maintaining model effectiveness.
What are potential implications of reducing the number of training eras on model performance
Reducing the number of training eras in a dataset could have several potential implications on model performance:
Loss of Environmental Diversity: Fewer training eras may result in a loss of environmental diversity, limiting the exposure of models to different scenarios and contexts present in real-world applications.
Overfitting Risk: With fewer distinct environments represented in the data, there is an increased risk of overfitting as models might learn patterns specific only to those limited environments rather than generalizing well across diverse settings.
Generalization Challenges: Models trained on a reduced set of eras may struggle with generalization when faced with unseen environments during testing or deployment.
4Computational Efficiency Improvement: On a positive note, reducing training eras could lead to improved computational efficiency during model training as less computation would be required per split calculation.
How might directional era splitting impact decision boundaries differently from traditional methods
Directional era splitting impacts decision boundaries differently from traditional methods by considering not just impurity reduction but also directional consistency across different eras (environments). Here are some key differences:
1Incorporating Directionality: Traditional methods focus solely on impurity reduction metrics without considering whether splits maintain consistent directions across different environments.
2Invariant Signal Learning: Directional era splitting aims at learning invariant signals present consistently across all environments while disregarding spurious signals that vary between environments
3Improved Generalization: By prioritizing splits that exhibit consistent directional improvements across all eras, directional era splitting enhances generalization capabilities by promoting robust decisions that hold true regardless of environmental variations
4**Complex Decision Boundaries: The use of directionality allows for more complex decision boundaries that capture underlying patterns common among various environments rather than relying solely on local optimization within individual datasets