The Wireless Sensor Network (WSN) has limitations in bandwidth and computational resources as they have limited communication and storage capabilities. WSN consists of cameras, which have some local image processing and one or more central computers, where image data from multiple cameras is further processed and fused. Because of these limitations, the encoding techniques used for transmitting the image data should be efficient in order to make use of the available resources properly. A new sampling method is also introduced in the Image/video encoder of the WSN called Compressed Sensing (CS), which is the process of acquiring and reconstructing a signal that is supposed to be sparse or compressible, thus reducing the computational complexity. The image is divided into dense and sparse components by applying 2 levels of wavelet transform. The dense component uses the standard encoding procedure such as JPEG and the sparse measurements obtained from the sparse components are encoded by the techniques such as Exponential Golomb coding followed by Run-length encoding and arithmetic coding and the performances in terms of compression ratio and bits per pixel are compared. The recovery algorithm may be anyone supporting the compressed sensing technique such as OMP, POCS etc. In this work, the measurements (used in CS) and the predicted sparse components as the initial values, the projection onto convex set (POCS) recovery algorithm is used to get back the original sparse components of two levels and hence the original image by applying the inverse of transform to the dense and recovered sparse components.
[1]
Reza Pournaghi.
Recovery of Compressive Sensed Images With Piecewise Autoregressive Modeling
,
2009
.
[2]
J. Romberg,et al.
Imaging via Compressive Sampling
,
2008,
IEEE Signal Processing Magazine.
[3]
Justin Romberg,et al.
Practical Signal Recovery from Random Projections
,
2005
.
[4]
Teresa H. Y. Meng,et al.
Variable compression using JPEG
,
1994,
1994 Proceedings of IEEE International Conference on Multimedia Computing and Systems.
[5]
Marcial Clotet Altarriba,et al.
Study, design and implementation of robust entropy coders
,
2010
.
[6]
E.J. Candes,et al.
An Introduction To Compressive Sampling
,
2008,
IEEE Signal Processing Magazine.
[7]
Xiangjun Zhang,et al.
Image Interpolation by Adaptive 2-D Autoregressive Modeling and Soft-Decision Estimation
,
2008,
IEEE Transactions on Image Processing.
[8]
Feng Wu,et al.
Image Coding on Quincunx Lattice with Adaptive Lifting and Interpolation
,
2007,
2007 Data Compression Conference (DCC'07).
[9]
Lu Gan.
Block Compressed Sensing of Natural Images
,
2007,
2007 15th International Conference on Digital Signal Processing.