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Wireless Personal Communications

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01-07-2014

Efficient Hardware-Based Image Compression Schemes for Wireless Sensor Networks: A Survey

Authors: Khamees Khalaf Hasan, Umi Kalthum Ngah, Mohd Fadzli Mohd Salleh

Published in: Wireless Personal Communications | Issue 2/2014

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Abstract

Multidimensional sensors, such as digital camera sensors in the visual sensor networks VSNs generate a huge amount of information compared with the scalar sensors in the wireless sensor networks WSNs. Processing and transmitting such data from low power sensor nodes is a challenging issue through their limited computational and restricted bandwidth requirements in a hardware constrained environment. Source coding can be used to reduce the size of vision data collected by the sensor nodes before sending it to its destination. With image compression, a more efficient method of processing and transmission can be obtained by removing the redundant information from the captured image raw data. In this paper, a survey of the main types of the conventional state of the art image compression standards such as JPEG and JPEG2000 is provided. A literature review of their advantages and shortcomings of the application of these algorithms in the VSN hardware environment is specified. Moreover, the main factors influencing the design of compression algorithms in the context of VSN are presented. The selected compression algorithm may have some hardware-oriented properties such as; simplicity in coding, low memory need, low computational load, and high-compression rate. In this survey paper, an energy efficient hardware based image compression is highly requested to counter the severe hardware constraints in the WSNs.

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Title: Efficient Hardware-Based Image Compression Schemes for Wireless Sensor Networks: A Survey
Authors: Khamees Khalaf Hasan
Umi Kalthum Ngah
Mohd Fadzli Mohd Salleh
Publication date: 01-07-2014
Publisher: Springer US
Published in: Wireless Personal Communications / Issue 2/2014
Print ISSN: 0929-6212
Electronic ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-013-1588-8

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Fast Convergence Algorithm for Earthquake Prediction Using Electromagnetic Fields Excited by SLF/ELF Horizontal Magnetic Dipole and Schumann Resonance

Angle-of-Arrival Estimation of Multipath Signals in A Passive Coherent Location System Using OFDM-Based Illuminators

Interference Studies Between Adjacent Satellite Communications Systems operating Above 10 GHz and Using Power Control as Fade Mitigation Technique