Energy modeling of Hoeffding tree ensembles

Energy consumption reduction has been an increasing trend in machine learning over the past few years due to its socio-ecological importance. In new challenging areas such as edge computing, energy consumption and predictive accuracy are key variables during algorithm design and implementation. State-of-the-art ensemble stream mining algorithms are able to create highly accurate predictions at a substantial energy cost. This paper introduces the nmin adaptation method to ensembles of Hoeffding tree algorithms, to further reduce their energy consumption without sacrificing accuracy. We also present extensive theoretical energy models of such algorithms, detailing their energy patterns and how nmin adaptation affects their energy consumption. We have evaluated the energy efficiency and accuracy of the nmin adaptation method on five different ensembles of Hoeffding trees under 11 publicly available datasets. The results show that we are able to reduce the energy consumption significantly, by 21% on average, affecting accuracy by less than one percent on average.

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Change of Elastic Wave Velocity in Granite after Radiation Exposure and Prospects for Energy Consumption Reduction in Ore Pretreatment

Физико-технические проблемы разработки полезных ископаемых ◽

10.15372/ftprpi20190219 ◽

2019 ◽

Keyword(s):

Energy Consumption ◽

Elastic Wave ◽

Radiation Exposure ◽

Wave Velocity ◽

Elastic Wave Velocity ◽

Energy Consumption Reduction ◽

Ore Pretreatment ◽

Consumption Reduction

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Implementation of Stack Data Placement and Run Time Management Using a Scratch-Pad Memory for Energy Consumption Reduction of Embedded Applications

IEICE Transactions on Fundamentals of Electronics Communications and Computer Sciences ◽

10.1587/transfun.e94.a.2597 ◽

2011 ◽

Vol E94-A (12) ◽

pp. 2597-2608 ◽

Cited By ~ 1

Author(s):

Lovic GAUTHIER ◽

Tohru ISHIHARA

Keyword(s):

Energy Consumption ◽

Time Management ◽

Data Placement ◽

Energy Consumption Reduction ◽

Scratch Pad Memory ◽

Consumption Reduction ◽

Run Time ◽

Embedded Applications

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Energy-aware very fast decision tree

International Journal of Data Science and Analytics ◽

10.1007/s41060-021-00246-4 ◽

2021 ◽

Author(s):

Eva García-Martín ◽

Niklas Lavesson ◽

Håkan Grahn ◽

Emiliano Casalicchio ◽

Veselka Boeva

Keyword(s):

Energy Consumption ◽

Decision Tree ◽

Concept Drift ◽

Algorithm Design ◽

Energy Aware ◽

Battery Capacity ◽

Very Fast Decision Tree ◽

Public Datasets ◽

Additional Constraints ◽

Fast Decision

AbstractRecently machine learning researchers are designing algorithms that can run in embedded and mobile devices, which introduces additional constraints compared to traditional algorithm design approaches. One of these constraints is energy consumption, which directly translates to battery capacity for these devices. Streaming algorithms, such as the Very Fast Decision Tree (VFDT), are designed to run in such devices due to their high velocity and low memory requirements. However, they have not been designed with an energy efficiency focus. This paper addresses this challenge by presenting the nmin adaptation method, which reduces the energy consumption of the VFDT algorithm with only minor effects on accuracy. nmin adaptation allows the algorithm to grow faster in those branches where there is more confidence to create a split, and delays the split on the less confident branches. This removes unnecessary computations related to checking for splits but maintains similar levels of accuracy. We have conducted extensive experiments on 29 public datasets, showing that the VFDT with nmin adaptation consumes up to 31% less energy than the original VFDT, and up to 96% less energy than the CVFDT (VFDT adapted for concept drift scenarios), trading off up to 1.7 percent of accuracy.

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