Computer Science and Information Engineering

Hsing-Shao Liu1 , Chi-Cheng Chuang2 , Chih-Chung Lin2 , Ray-I Chang This email address is being protected from spambots. You need JavaScript enabled to view it.2, Chia-Hui Wang3 and Ching-Chia Hsieh1

1Department of Information Management, National Taiwan University, Taipei, Taiwan 10617, R.O.C.
2Department of Engineering Science, National Taiwan University, Taipei, Taiwan 10617, R.O.C.
3Department of Computer Science and Information Engineering, Ming Chuan University, Taoyuan, Taiwan 33348, R.O.C.

 

Received: December 23, 2010
Accepted: December 31, 2010
Publication Date: September 1, 2011

Download Citation: ||https://doi.org/10.6180/jase.2011.14.3.08  


ABSTRACT

Ubiquitous sensor networks (USNs) implemented by wireless sensor networks (WSNs) play a critical role for the next generation ubiquitous networks. Nowadays, the evolving “Internet of Thing”, which has been deemed as a mainstream of future Internet, raises even more the already high hopes of WSN and has attracted the interest of the research community worldwide. Since the sensor nodes are often equipped with the battery that usually cannot be replaced or recharged, the way to extend their lifetime becomes a critical issue. Because radio communication is the main cause of power consumption for sensor nodes, several approaches have been proposed to save power by compressing the volume of sensing data during communication. In this paper, we propose an efficient compression mechanism for WSN by treating sensing data as the raw data of an image for compression. We also introduce the user-acceptable data error which can be defined by a user to enhance the compression efficiency. Experimental results show that our mechanism can reach a better compression ratio compared with other approaches in either higher or lower correlated data scenario. More power can be saved during the radio communication due to lower volume of data. Furthermore, since our mechanism only involves addition and subtraction operations, the extra calculating burden resulted from compression can be minimized and thus, the extra power used to such calculation is negligible compared with the power used for transmitting a single bit data.


Keywords: Ubiquitous Sensor Network, Wireless Sensor Network, Internet of Thing, Data Compression, JPEG-LS


REFERENCES

  1. [1] Akyildiz, I., Su, W., Sankarasubramaniam, Y. and Cayirci, E., “Wireless Sensor Networks: A Survey,” Journal of Computer Networks, Vol. 38, pp. 393422 (2002).
  2. [2] García-Hernández, C. F., Ibargüengoytia-González, P. H., García-Hernández, J. and Pérez-Díaz, J. A., “Wireless Sensor Networks and Applications: A Survey,” International Journal of Computer Science and Network Security, Vol. 7, pp. 264273 (2007).
  3. [3] Culler, D., Estrin, D. and Srivastava, M., “Guest Editors’ Introduction: Overview of Sensor Network,” IEEE Computer Society, Vol. 37, pp. 4149 (2004).
  4. [4] Emara, K. A., Abdeen, M. and Hashem, M., “A Gateway-Based Framework for Transparent Interconnection between WSN and IP Network,” IEEE EUROCON ‘09, pp. 17751780 (2009).
  5. [5] Zahariadis, T., Trakadas, P., Leligou, H., Papadopoylos, K., Ladis, E., Tselikis, C., Vangelatos, C., Besson, L., Manner, J., Loupis, M., Alvarez, F. and Papaefstathiou, Y., “Securing Wireless Sensor Networks towards a Trusted Internet of Things,” In: Tselentis, G., Domingue, J., Galis, A., Gavras, A., Hausheer, D., Krco, S., Lotz, V. and Zahariadis, T., editors. Towards the Future Internet - A European Research Perspective, IOS Press, pp. 4756 (2009).
  6. [6] Yun, Y. and Xia, Y., “Maximizing the Lifetime of Wireless Sensor Networks with Mobile Sink in Delay-Tolerant Applications,” IEEE Transactions on Mobile Computing, Vol. 9, pp. 13081318 (2010).
  7. [7] Anastasi, G., Conti, M., Di Francesco, M. and Passarella, A., “How to Prolong the Lifetime of Wireless Sensor Networks,” In: Denko, M. and Yang, L., editors. Mobile Ad Hoc and Pervasive Communications, American Scientific Publishers, Valencia, CA, USA (2006).
  8. [8] Pottie, G. and Kaiser, W., “Wireless Integrated Network Sensors,” Communications of the ACM, Vol. 43, pp. 5158 (2000).
  9. [9] Kimura, N. and Latifi, S., “A Survey on Data Compression in Wireless Sensor Networks,” Proceedings of the International Conference on Information Technology: Coding and Computing, Las Vegas, Nevada, USA, pp. 813 (2005).
  10. [10] Arici, T., Gedik, B., Altunbasak, Y. and Liu, L., “PINCO: A Pipelined In-Network Compression Scheme for Data Collection in Wireless Sensor Networks,” Proceedings of 12th International Conference on Computer Communications and Networks (2003).
  11. [11] Marcelloni, F. and Vecchio, M., “A Simple Algorithm for Data Compression in Wireless Sensor Networks,” IEEE Communication Letters, Vol. 12, pp. 411413 (2008).
  12. [12] Tharini, C. and Ranjan, P. V., “Design of Modified Adaptive Huffman Data Compression Algorithm for Wireless Sensor Network,” Journal of Computer Science, Vol. 5, pp. 466470 (2009).
  13. [13] Javed, M. Y. and Nadeem, A., “Data Compression through Adaptive Huffman Coding Schemes,” IEEE TENCON Proceedings, Vol. 2, pp. 187190 (2000).
  14. [14] Zhu, X., Ying, S. and Ling, L., “Multimedia Sensor Networks Design for Smart Home Surveillance,” IEEE CCDC, Yantai, Shandong, pp. 431435 (2008).
  15. [15] Räty, T., Oikarinen, J., Nieminen, M. and Lindholm, M., “Sensor Data Collection of the Single Location Surveillance Point System,” IEEE ICIS, Portland, OR, pp. 382387 (2008).
  16. [16] Weinberger, M. J. and Seroussi, G., “The LOCO-I Lossless Image Compression Algorithm Principles and Standardization into JPEG-LS,” IEEE Transactions on Image Processing, Vol. 9, pp. 13091324 (2000).
  17. [17] Wallace, G. K., “The JPEG Still Picture Compression Standard,” Communications of the ACM, Vol. 34, pp. 3044 (1991).
  18. [18] ISO/IEC 14495-1, ITU Recommendation T.87, Information Technology - Lossless and Near-Lossless Compression of Continuous-Tone Still Images (1999).
  19. [19] Shan, Q., Brown, D. and Liu, Y., “Wireless Temperature Sensor Network for Refrigerated Vehicles,” IEEE ISIE, Vol. 3, pp. 12091214 (2005).
  20. [20] Ahonen, T., Virrankoski, R. and Elmusrati, M., “Greenhouse Monitoring with Wireless Sensor Network,” 2008 Proceedings of IEEE/ASME International Conference on Mechatronic and Embedded Systems and Applications, Beijing, China, pp. 403408 (2008).
  21. [21] The Planetary Atmospheres Node of the Planetary Data System (PDS) in NASA website [Internet]. Available from: http://pds-atmospheres.nmsu.edu/.
  22. [22] The PAST website [Internet]. Available from: http:// folk.uio.no/ohammer/past/.
  23. [23] The IEEE 802.15.4 module for NS2 website [Internet]. Available from: http://www-ee.ccny.cuny.edu/zheng/ pub/.

Latest Articles

A Novel Business Administration Big Data Clustering Optimization Method Based on Active Density Peak and Salpa Swarm Algorithm
A Novel Business Administration Big Data Clustering Optimization Method Based on Active Density Peak and Salpa Swarm AlgorithmVolume 28, Issue 3 (In Press)

Read more: ...

Methodological Approach to Selecting State Equations and Adsorption Isotherms
Methodological Approach to Selecting State Equations and Adsorption IsothermsVolume 28, Issue 3 (In Press)

Read more: ...

Study on photocatalytic and antibacterial ability of TiO2 and TiO2-SiO2 coatings
Study on photocatalytic and antibacterial ability of TiO2 and TiO2-SiO2 coatingsVolume 28, Issue 3 (In Press)

Read more: ...

Energy-Efficient Hybrid Protocol with Optimization Inference Model for WBANs
Energy-Efficient Hybrid Protocol with Optimization Inference Model for WBANsVolume 28, Issue 3 (In Press)

Read more: ...

Cross-scales analysis of shear behavior in Fontainebleau sandstone
Cross-scales analysis of shear behavior in Fontainebleau sandstoneVolume 28, Issue 3 (In Press)

Read more: ...

Application of RSM for the Optimization of Steel Fibre Reinforced Concrete Quality at Elevated Temperatures
Application of RSM for the Optimization of Steel Fibre Reinforced Concrete Quality at Elevated TemperaturesVolume 28, Issue 2 (In Press)

Read more: ...

Single Shot MultiBox Detector-based Feature Fusion Model for Building Object Detection
Single Shot MultiBox Detector-based Feature Fusion Model for Building Object DetectionVolume 28, Issue 2 (In Press)

Read more: ...

Influence of Calcium Carbonate Content on Properties of Natural Rubber and Acrylic Blends for Coating Applications
Influence of Calcium Carbonate Content on Properties of Natural Rubber and Acrylic Blends for Coating ApplicationsVolume 28, Issue 2 (In Press)

Read more: ...

Alkaline pretreatment of banana pseudostem waste for green cellulose fiber composite materials
Alkaline pretreatment of banana pseudostem waste for green cellulose fiber composite materialsVolume 28, Issue 2 (In Press)

Read more: ...