Modification of Random Forest Based Approach for Streaming Data with Concept Drift

We are living in the age of big data, a majority of which is stream data. The real-time processing of this data requires careful consideration from different perspectives. Concept drift is a change in the data’s underlying distribution, a significant issue, especially when learning from data streams. It requires learners to be adaptive to dynamic changes. Random forest is an ensemble approach that is widely used in classical non-streaming settings of machine learning applications. At the same time, the Adaptive Random Forest (ARF) is a stream learning algorithm that showed promising results in terms of its accuracy and ability to deal with various types of drift. The incoming instances’ continuity allows for their binomial distribution to be approximated to a Poisson(1) distribution. In this study, we propose a mechanism to increase such streaming algorithms’ efficiency by focusing on resampling. Our measure, resampling effectiveness (ρ), fuses the two most essential aspects in online learning; accuracy and execution time. We use six different synthetic data sets, each having a different type of drift, to empirically select the parameter λ of the Poisson distribution that yields the best value for ρ. By comparing the standard ARF with its tuned variations, we show that ARF performance can be enhanced by tackling this important aspect. Finally, we present three case studies from different contexts to test our proposed enhancement method and demonstrate its effectiveness in processing large data sets: (a) Amazon customer reviews (written in English), (b) hotel reviews (in Arabic), and (c) real-time aspect-based sentiment analysis of COVID-19-related tweets in the United States during April 2020. Results indicate that our proposed method of enhancement exhibited considerable improvement in most of the situations.

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Deep learning framework for handling concept drift and class imbalanced complex decision-making on streaming data

Complex & Intelligent Systems ◽

10.1007/s40747-021-00456-0 ◽

2021 ◽

Author(s):

S. Priya ◽

R. Annie Uthra

Keyword(s):

Decision Making ◽

Deep Learning ◽

Concept Drift ◽

Class Imbalance ◽

Streaming Data ◽

Superior Performance ◽

Data Streaming ◽

Minority Class ◽

Concept Drift Detection

AbstractIn present times, data science become popular to support and improve decision-making process. Due to the accessibility of a wide application perspective of data streaming, class imbalance and concept drifting become crucial learning problems. The advent of deep learning (DL) models finds useful for the classification of concept drift in data streaming applications. This paper presents an effective class imbalance with concept drift detection (CIDD) using Adadelta optimizer-based deep neural networks (ADODNN), named CIDD-ADODNN model for the classification of highly imbalanced streaming data. The presented model involves four processes namely preprocessing, class imbalance handling, concept drift detection, and classification. The proposed model uses adaptive synthetic (ADASYN) technique for handling class imbalance data, which utilizes a weighted distribution for diverse minority class examples based on the level of difficulty in learning. Next, a drift detection technique called adaptive sliding window (ADWIN) is employed to detect the existence of the concept drift. Besides, ADODNN model is utilized for the classification processes. For increasing the classifier performance of the DNN model, ADO-based hyperparameter tuning process takes place to determine the optimal parameters of the DNN model. The performance of the presented model is evaluated using three streaming datasets namely intrusion detection (NSL KDDCup) dataset, Spam dataset, and Chess dataset. A detailed comparative results analysis takes place and the simulation results verified the superior performance of the presented model by obtaining a maximum accuracy of 0.9592, 0.9320, and 0.7646 on the applied KDDCup, Spam, and Chess dataset, respectively.

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Random Forest Based Approach for Concept Drift Handling

Communications in Computer and Information Science - Analysis of Images, Social Networks and Texts ◽

10.1007/978-3-319-52920-2_7 ◽

2017 ◽

pp. 69-77 ◽

Cited By ~ 6

Author(s):

Aleksei V. Zhukov ◽

Denis N. Sidorov ◽

Aoife M. Foley

Keyword(s):

Random Forest ◽

Concept Drift

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Concept Drift Detection on Streaming Data with Dynamic Outlier Aggregation

Lecture Notes in Business Information Processing - Process Mining Workshops ◽

10.1007/978-3-030-72693-5_16 ◽

2021 ◽

pp. 206-217

Author(s):

Ludwig Zellner ◽

Florian Richter ◽

Janina Sontheim ◽

Andrea Maldonado ◽

Thomas Seidl

Keyword(s):

Concept Drift ◽

Streaming Data ◽

Concept Drift Detection

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Data-driven decision support under concept drift in streamed big data

Complex & Intelligent Systems ◽

10.1007/s40747-019-00124-4 ◽

2019 ◽

Vol 6 (1) ◽

pp. 157-163 ◽

Cited By ~ 2

Author(s):

Jie Lu ◽

Anjin Liu ◽

Yiliao Song ◽

Guangquan Zhang

Keyword(s):

Decision Making ◽

Big Data ◽

Real Time ◽

Concept Drift ◽

High Volume ◽

Streaming Data ◽

Data Driven ◽

Research Directions ◽

Decision Outcomes ◽

Past Data

Abstract Data-driven decision-making ($$\mathrm {D^3}$$D3M) is often confronted by the problem of uncertainty or unknown dynamics in streaming data. To provide real-time accurate decision solutions, the systems have to promptly address changes in data distribution in streaming data—a phenomenon known as concept drift. Past data patterns may not be relevant to new data when a data stream experiences significant drift, thus to continue using models based on past data will lead to poor prediction and poor decision outcomes. This position paper discusses the basic framework and prevailing techniques in streaming type big data and concept drift for $$\mathrm {D^3}$$D3M. The study first establishes a technical framework for real-time $$\mathrm {D^3}$$D3M under concept drift and details the characteristics of high-volume streaming data. The main methodologies and approaches for detecting concept drift and supporting $$\mathrm {D^3}$$D3M are highlighted and presented. Lastly, further research directions, related methods and procedures for using streaming data to support decision-making in concept drift environments are identified. We hope the observations in this paper could support researchers and professionals to better understand the fundamentals and research directions of $$\mathrm {D^3}$$D3M in streamed big data environments.

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