Ecological Big Data Adaptive Compression Method Combining 1D Convolutional Neural Network and Switching Idea

Qiaoling Han,Yandong Zhao,Yue Zhao,Lei Liu

doi:10.1109/access.2020.2969216

Qiaoling Han, Yandong Zhao + Show 2 more

Open Access

https://doi.org/10.1109/access.2020.2969216

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Abstract

To address large data transmission requirements and high transmission power consumptions characterizing micro-environment monitoring systems that are commonly used in forest health and safety applications, we propose an ecological big data adaptive switching compression method based on a 1D convolutional neural network (1D CNN). First, to ensure that data samples apply to different compression dictionaries, a 1D CNN is used to classify the samples into two sets according to the characteristics of samples. Subsequently, based on the classification results, the switching factor $S$ is defined, such that the discrete cosine transform (DCT) predefined dictionary and the learning dictionary (K-SVD) can be used to adaptively achieve sparse expression and data compression. Finally, the orthogonal matching pursuit (OMP) algorithm reconstructs the sparse signal. To evaluate the feasibility and robustness of the proposed method, we conduct experiments on four types of data: air temperature (AT), air humidity (AH), soil temperature (ST), and soil humidity (SH). The results indicate that the proposed method, compared to K-SVD and DCT dictionary, exhibits excellent performance for all data samples having smaller sparse error (SE), smaller reconstruction error (RE), and larger compression ratio (CR) at different sparsity levels. In particular, when sparsity $K$ is 16, the reconstructed signal is the most similar to the original signal. In addition, the proposed method reduces power consumption by 79.90%, compared with uncompressed data transmission. Considering four factors, the adaptive switching compression method based on 1D CNN has higher reconstruction accuracy and lower power consumption than using only K-SVD or DCT dictionary.

Highlights

A micro-environment monitoring system, based on a realtime data acquisition method and device, can facilitate analysis and decision-making on forest fire warnings and forest health assessment through data analysis and mining, ensuring forest area security [1]–[3]
AND ANALYSIS the performance of the proposed method is demonstrated on the dataset, which consists of the four subdatasets air temperature (AT), air humidity (AH), soil temperature (ST), and soil moisture (SM)
According to the 5:5 principle, each subset is randomly divided into a training set and a testing set

Summary

INTRODUCTION

A micro-environment monitoring system, based on a realtime data acquisition method and device, can facilitate analysis and decision-making on forest fire warnings and forest health assessment through data analysis and mining, ensuring forest area security [1]–[3]. The method can adaptively select the most suitable dictionary for sparse expression according to the various ecological data characteristics. In this process, the classification of ecological data is an important factor affecting data compression performance. According to the switching strategy, a predefined dictionary and a learning dictionary are adaptively selected to complete the compression of the data samples. 2) LEARNING DICTIONARY K-SVD is a dictionary training algorithm based on large amounts of data, which performs the learning process through repeated sparse coding and dictionary updating. This process can be represented by an optimization problem: min.

EVALUATION INDEX

RESULTS AND ANALYSIS

COMPRESSION RATIOS OF DCT DICTIONARY AND K-SVD DICTIONARY

POWER CONSUMPTION TEST