Automatic Detection of Computer Network Traffic Anomalies based on Eccentricity Analysis

Martins, Rodrigo Siqueira

doi:10.1109/fuzz-ieee.2018.8491507

Cited by 9 publications

(4 citation statements)

References 19 publications

(29 reference statements)

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“…Besides, it has been shown that due to the recursion feature, TEDA is computationally more efficient and suitable for online and real-time applications. Other works in the literature also present similar results and conclusions [8], [10], [12], [27], [28]. The characteristics and advantages of the TEDA algorithm presented in these references have justified and motivated the choice of this algorithm, among several anomaly detection algorithms, for the implementation of the hardware architecture for streaming processes.…”

Section: Related Worksupporting

confidence: 62%

Hardware Architecture Proposal for TEDA Algorithm to Data Streaming Anomaly Detection

et al. 2021

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The amount of data in real-time, such as time series and streaming data, available today continues to grow. Being able to analyze this data the moment it arrives can bring an immense added value. However, it also requires a lot of computational effort and new acceleration techniques. As a possible solution to this problem, this paper proposes a hardware architecture for Typicality and Eccentricity Data Analytic (TEDA) algorithm implemented on Field Programmable Gate Arrays (FPGA) for use in data streaming anomaly detection. TEDA is based on a new approach to outlier detection in the data stream context. The suggested design has a full parallel input of N elements and a 3-stage pipelined architecture to reduce the critical path and thus optimize the throughput. In order to validate the proposals, results of the occupation and throughput of the proposed hardware are presented. The design reached a speed of up to 693x, compared to other software platforms, with a throughput of up to 10.96 MSPs (Mega Sample Per second), using a small portion of the target FPGA resources. Besides, the bit accurate simulation results are also presented. This work is a pioneer in the hardware implementation of the TEDA technique in FPGA. The project aims to Xilinx Virtex-6 xc6vlx240t-1ff1156 as the target FPGA.

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Section: Related Worksupporting

confidence: 62%

Hardware Architecture Proposal for TEDA Algorithm to Data Streaming Anomaly Detection

et al. 2021

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“…In the following subsections, the main mathematical concepts behind the methodology are shown and what makes it so flexible that it can be used for the development of a variety of algorithms, such as: anomalies and failure detection [ 49 ], image processing, clustering [ 50 , 51 ], classification [ 52 ], regression [ 53 ], forecast, control, filtering, big data [ 54 ], and traffic analysis [ 55 ], among others.…”

Section: Typicality and Eccentricity Data Analyticsmentioning

confidence: 99%

An Evolving TinyML Compression Algorithm for IoT Environments Based on Data Eccentricity

Signoretti

Silva

Andrade

et al. 2021

Sensors

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Currently, the applications of the Internet of Things (IoT) generate a large amount of sensor data at a very high pace, making it a challenge to collect and store the data. This scenario brings about the need for effective data compression algorithms to make the data manageable among tiny and battery-powered devices and, more importantly, shareable across the network. Additionally, considering that, very often, wireless communications (e.g., low-power wide-area networks) are adopted to connect field devices, user payload compression can also provide benefits derived from better spectrum usage, which in turn can result in advantages for high-density application scenarios. As a result of this increase in the number of connected devices, a new concept has emerged, called TinyML. It enables the use of machine learning on tiny, computationally restrained devices. This allows intelligent devices to analyze and interpret data locally and in real time. Therefore, this work presents a new data compression solution (algorithm) for the IoT that leverages the TinyML perspective. The new approach is called the Tiny Anomaly Compressor (TAC) and is based on data eccentricity. TAC does not require previously established mathematical models or any assumptions about the underlying data distribution. In order to test the effectiveness of the proposed solution and validate it, a comparative analysis was performed on two real-world datasets with two other algorithms from the literature (namely Swing Door Trending (SDT) and the Discrete Cosine Transform (DCT)). It was found that the TAC algorithm showed promising results, achieving a maximum compression rate of 98.33%. Additionally, it also surpassed the two other models regarding the compression error and peak signal-to-noise ratio in all cases.

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“…The paper published by [18] brings a study for anomaly detection in TCP / IP networks. The purpose of the paper is to detect computer network anomalies in the process of virtual machine (VM) live migration from local to cloud, by comparing this approach between TEDA, clustering K-Means, and static analysis.…”

Section: Related Workmentioning

confidence: 99%

Hardware Architecture Proposal for TEDA algorithm to Data Streaming Anomaly Detection

da Silva,

Coutinho,

Santos

et al. 2020

Preprint

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Automatic Detection of Computer Network Traffic Anomalies based on Eccentricity Analysis

Cited by 9 publications

References 19 publications

Hardware Architecture Proposal for TEDA Algorithm to Data Streaming Anomaly Detection

Hardware Architecture Proposal for TEDA Algorithm to Data Streaming Anomaly Detection

An Evolving TinyML Compression Algorithm for IoT Environments Based on Data Eccentricity

Hardware Architecture Proposal for TEDA algorithm to Data Streaming Anomaly Detection

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