Hoeffding Trees with Nmin Adaptation
Autor: | Emiliano Casalicchio, Niklas Lavesson, Håkan Grahn, Eva García-Martín, Veselka Boeva |
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Rok vydání: | 2018 |
Předmět: |
information systems and management
FOS: Computer and information sciences Computer Science - Machine Learning Computational complexity theory Computer science data stream mining Decision tree Machine Learning (stat.ML) 02 engineering and technology Machine Learning (cs.LG) energy aware machine learning Software Statistics - Machine Learning 020204 information systems 0202 electrical engineering electronic engineering information engineering signal processing energy efficiency computer networks and communications Computer Sciences Data stream mining business.industry green artificial intelligence Hoeffding trees Energy consumption probability and uncertainty Tree (data structure) Datavetenskap (datalogi) statistics Scalability 020201 artificial intelligence & image processing statistics probability and uncertainty business Algorithm Energy (signal processing) |
Zdroj: | DSAA |
DOI: | 10.1109/dsaa.2018.00017 |
Popis: | Machine learning software accounts for a significant amount of energy consumed in data centers. These algorithms are usually optimized towards predictive performance, i.e. accuracy, and scalability. This is the case of data stream mining algorithms. Although these algorithms are adaptive to the incoming data, they have fixed parameters from the beginning of the execution. We have observed that having fixed parameters lead to unnecessary computations, thus making the algorithm energy inefficient. In this paper we present the nmin adaptation method for Hoeffding trees. This method adapts the value of the nmin parameter, which significantly affects the energy consumption of the algorithm. The method reduces unnecessary computations and memory accesses, thus reducing the energy, while the accuracy is only marginally affected. We experimentally compared VFDT (Very Fast Decision Tree, the first Hoeffding tree algorithm) and CVFDT (Concept-adapting VFDT) with the VFDT-nmin (VFDT with nmin adaptation). The results show that VFDT-nmin consumes up to 27% less energy than the standard VFDT, and up to 92% less energy than CVFDT, trading off a few percent of accuracy in a few datasets. Accepted at: The 5th IEEE International Conference on Data Science and Advanced Analytics (DSAA 2018) |
Databáze: | OpenAIRE |
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