Time Series Classification Using Compression Distance of Recurrence Plots

Silva, Diego F.; Souza, Valdir de; Batista, Gustavo E. A. P. A.

doi:10.1109/icdm.2013.128

Cited by 69 publications

(52 citation statements)

References 34 publications

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“…Even without extracting texture features, the most similar work to ours is presented by Silva et al [2] with the Recurrence Patterns Compression Distance (RPCD) for time series classification. The RPCD applies a video compression based distance measure (CK-1) in an 1-NN algorithm to estimate the similarity between two time series represented by recurrence plot.…”

Section: Related Workmentioning

confidence: 96%

“…In summary, TFRP uses a Support Vector Machine (SVM) algorithm with four techniques for extracting texture features from recurrence plots. We show in our experimental evaluation with 38 time series data sets that TFRP is very competitive with state-of-the-art methods such as 1-NN with Euclidean distance, Dynamic Time Warping and Recurrence Patterns Compression Distance (RPCD) [2]. RPCD is our previous attempt to classify time series using recurrence plots and CK-1 [3], a distance measure between images that uses video compression algorithms.…”

Section: Introductionmentioning

confidence: 99%

“…These data sets have standard partitions of training and testing, further facilitating the execution of experiments and the comparison of results. Similarly to [2], we decided to exclude all synthetic data sets since they were generated for a specific purpose or algorithm. Thus, we use 38 data sets in our experiments.…”

Section: Experimental Evaluationmentioning

confidence: 99%

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Extracting Texture Features for Time Series Classification

Souza

Silva

Batista

2014

2014 22nd International Conference on Pattern Recognition

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Abstract-Time series are present in many pattern recognition applications related to medicine, biology, astronomy, economy, and others. In particular, the classification task has attracted much attention from a large number of researchers. In such a task, empirical researches has shown that the 1-Nearest Neighbor rule with a distance measure in time domain usually performs well in a variety of application domains. However, certain time series features are not evident in time domain. A classical example is the classification of sound, in which representative features are usually present in the frequency domain. For these applications, an alternative representation is necessary. In this work we investigate the use of recurrence plots as data representation for time series classification. This representation has well-defined visual texture patterns and their graphical nature exposes hidden patterns and structural changes in data. Therefore, we propose a method capable of extracting texture features from this graphical representation, and use those features to classify time series data. We use traditional methods such as Grey Level Co-occurrence Matrix and Local Binary Patterns, which have shown good results in texture classification. In a comprehensible experimental evaluation, we show that our method outperforms the state-ofthe-art methods for time series classification.

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Section: Related Workmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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Extracting Texture Features for Time Series Classification

Souza

Silva

Batista

2014

2014 22nd International Conference on Pattern Recognition

Self Cite

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“…Furthermore, synchronicity and convergence are also examined among member nations of the Euro region for GDP using cross recurrence analysis [25]. Silva et al [26] gave an overview of recurrence plots as a representation domain for time series classification, in which CampanaKeogh (CK-1) and Kolmogorov complexity based distances are used to measure the closeness between recurrence plots and to estimate image similarity, respectively.…”

Section: Literature Reviewmentioning

confidence: 99%

Recurrence Based Similarity Identification of Climate Data

Bai

Hira²,

Parag

2017

Discrete Dynamics in Nature and Society

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Climate change has become a challenging and emerging research problem in many research related areas. One of the key parameters in analyzing climate change is to analyze temperature variations in different regions. The temperature variation in a region is periodic within the interval. Temperature variations, though periodic in nature, may vary from one region to another and such variations are mainly dependent on the location and altitude of the region and also on other factors like the nearness of sea and vegetation.In this paper, we analyze such periodic variations using recurrence plot (RP), cross recurrence plot (CRP), recurrence rate (RR), and correlation of probability of recurrence (CPR) methods to find similarities of periodic variations between and within climatic regions and to identify their connectivity trend. First, we test the correctness of our method by applying it on voice and heart rate data and then experimentation is performed on synthetic climate data of nine regions in the United States and eight regions in China. Finally, the accuracy of our approach is validated on both real and synthetic datasets and demonstrated using ANOVA, Kruskal-Wallis, and z-statistics significance tests.

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“…There are structural patterns in recurrence plots which can be used to determine the similarity between two video sequences, which is necessary for classification, so measuring the similarity between two recurrence plots, needed for video classification in order to event detection in video sequences. In [5] the CK-1 distance used to measure the similarity between unthresholded recurrence plots that were generated from time series and results show the combination of the CK-1 distance measure together with unthresholded recurrence plots results in higher classification accuracy for time series which represent the shape. Related to energy and power [6], check the effect of similarity measures is a necessary step for the optimized design and development of efficient clustering based models, predictors and controllers of time dependent processes such as building energy consumption patterns.…”

Section: Introductionmentioning

confidence: 99%

FESM: An Analytical Framework for Elastic Similarity Measures Based Time Series Pattern Recognition

Esmaeili¹,

Faez²

2016

IJCA

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Compare the similarity of time series is a key for most tasks and there are various similarity measures which measure the similarity of time series. Similarity measures are the basis of time series research, they are quite important for improving the efficiency and accuracy of the time series pattern recognition tasks. Therefore selection the best similarity measures are very essential. On this issue, in this paper an analytical framework for elastic similarity measures based time series pattern recognition as, FESM for short, is proposed. FESM consists of three main components: 1) Classification of elastic similarity measures of time series, 2) Comparative evaluation of classified similarity measures based on proposed qualitative evaluation criteria, and 3) Application scopes of classified similarity measures. FESM will be proper for the quick understanding and comparing of time series similarity measures, and selection the best of existing similarity measures for respective time series pattern recognition tasks. General TermsPattern Recognition

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Time Series Classification Using Compression Distance of Recurrence Plots

Cited by 69 publications

References 34 publications

Extracting Texture Features for Time Series Classification

Extracting Texture Features for Time Series Classification

Recurrence Based Similarity Identification of Climate Data

FESM: An Analytical Framework for Elastic Similarity Measures Based Time Series Pattern Recognition

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