With the spurt in the amount of data (Image, video, audio, speech, & text) available on the net, there is a huge demand for memory & bandwidth savings. One has to achieve this, by maintaining the quality & fidelity of the data acceptable to the end user. Wavelet transform is an important and practical tool for data compression. Set partitioning in hierarchal trees (SPIHT) is a widely used compression algorithm for wavelet transformed images. Among all wavelet transform and zero-tree quantization based image compression algorithms SPIHT has become the benchmark state-of-the-art algorithm because it is simple to implement & yields good results. In this paper we present a comparative study of various wavelet families for image compression with SPIHT algorithm. We have conducted experiments with Daubechies, Coiflet, Symlet, Bi-orthogonal, Reverse Bi-orthogonal and Demeyer wavelet types. The resulting image quality is measured objectively, using peak signal-to-noise ratio (PSNR), and subjectively, using perceived image quality (human visual perception, HVP for short). The resulting reduction in the image size is quantified by compression ratio (CR)

Mamatha, Y.A.

Ramesh, K.N.

Sreenivasa Murthy, A.

ICTACT Journal on Image and Video Processing

A. Sreenivasa Murthy

K.N. Ramesh

Y.A. Mamatha

Directory of Open Access Journals

A SREENIVASA MURTHY et al.: PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION 932 PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION A. Sreenivasa Murthy1, K.N. Ramesh2 and Y.A. Mamatha3 Department of Electronics and Communication Engineering, Bangalore University, India E-mail: 1uvceasm@gmail.com, 2rkestur@gmail.com, 3mamatha.ya52@gmail.comAbstract With the spurt in the amount of data (Image, video, audio, speech, & text)  available  on  the  net,  there  is  a  huge  demand  for memory  & bandwidth  savings.  One  has  to  achieve  this,  by  maintaining  the quality  &  fidelity  of  the  data  acceptable  to  the  end  user.  Wavelet transform is an important and practical tool for data compression. Set partitioning in hierarchal trees (SPIHT) is a widely used compression algorithm  for  wavelet  transformed  images.  Among  all  wavelet transform  and  zero-tree  quantization  based  image  compression algorithms  SPIHT  has  become  the  benchmark  state-of-the-art algorithm because it is simple to implement & yields good results. In this paper we present a comparative study of various wavelet families for image compression with  SPIHT algorithm. We have conducted experiments with Daubechies, Coiflet, Symlet, Bi-orthogonal, Reverse Bi-orthogonal  and  Demeyer  wavelet  types.  The  resulting  image quality  is  measured  objectively,  using  peak  signal-to-noise  ratio (PSNR),  and  subjectively,  using  perceived  image  quality  (human visual  perception,  HVP  for  short).  The  resulting  reduction  in  the image size is quantified by compression ratio (CR).  Keywords:  SPIHT, DWT, Image Compression 1. INTRODUCTION  Social networking and the always connected personal digital assistants  (PDA)  and  more  popularly  called  the  smart  phones paradigm have made a transformational impact on the real social lives of the connected world. As a consequence there is a huge burst in demand for image storage and transmission. Images and videos are uploaded and downloaded anytime, anywhere. Image storage and transmission is resource intensive, in such a scenario it is imperative  to  optimize  storage  and  transmission  bandwidth. Current popular  method of  compression  is  DCT [9],[10]. DCT based compression represents image as a superposition of cosine functions of different frequencies [11]. DCT is characterized by high speed and low cost and hence popular. DCT uses uniform sized  square  block  size  which  reduces  the  complexity  of compression. The uniform block size does not factor the irregular shape within the uniform block. This is the fundamental drawback of  DCT  which  is  known  as  blocking  effect.  Wavelets  are extensively used due to their portability for image processing and particularly  in  image  compression.  Wavelets  works  on  the principle of hierarchically decomposing an image into successful lower  resolution  components  and  their  associated  detailed components. At each level, the reference and detailed components contain  the  information  required  to  reconstruct  the  reference component at the next higher resolution level. Wavelet provide good compression ratios and performed better when compared to popular techniques like JPEG in terms of signal to noise ratio and image quality. Unlike JPEG, it does not have blocking effect and allows  for  seamless  degradation  of  the  whole  image  quality. However  the  implementation  complexity  of  wavelet  based compression  is  higher  than  DCT.  A  study  of  the  performance difference of the discrete cosine transform (DCT) and the wavelet transform for both image and video coding, was studied in the paper by Xiang et.al [8]. Performance analysis and comparison of wavelet families using for image compression of different images was studied in the paper [12]. This work attempts to perform an analysis  of  family  of  wavelets  with  the  SPIHT  algorithm  for image compression. Wavelet [2],[3] is a small wave of limited duration, localized in time and scale and has an average value of zero.  In  recent  times,  much  of  the  research  activities  in  image coding  have  been  focused  on  the  discrete  wavelet  transform (DWT), which has become a standard tool in image compression applications  because  of  their  data  reduction  capability,  low computational complexity, & possibility of constructing their own basis  function  [4],[5],[8].  In  this  paper,  Daubechies,  Coiflet, Symlet,  Bi-orthogonal,  Reverse  Bi-orthogonal  and  Demeyer wavelet types are considered for image compression using SPIHT algorithm.  Of  most  algorithms  developed,  SPIHT  algorithm  is treated  as  one  of  the  most  significant  among  these  algorithms because  it’s  fully  embedded  codec,  optimized  for  progressive image transmission and provides good quality image and coding efficiency.  2. SPIHT ALGORITHM  SPIHT [7] was introduced by Said and Pearlman. The SPIHT algorithm is a highly refined version of the EZW [6] algorithm. The  wavelet  based  SPIHT  algorithm  involves  coding  of  the wavelet transform of an image by set partitioning along spatial orientation trees and progressive bit-plane coding of significant coefficients. The steps involved in the SPIHT algorithm are: Step 1: Initialization.    The value of n is calculated to set threshold 2n using the equation          j i c n , 2 max log    (1)   where,  ci,j  is  the  wavelet  coefficient  at  co-ordinate  (i,  j). Three lists such as LSP (list of significant pixels), LIP (list of insignificant pixels) and LIS (list of insignificant set) are constructed.  LSP  is  initialized  as  an  empty  set.  LIP  is initialized to contain all pixels in low pass sub band. LIS is initialized to contain all pixels in low pass sub band that have descendants and forms roots of spatial tree. Step 2: Sorting pass.    The sorting pass is made for the first threshold. This pass involves checking the data several times and selecting ISSN: 0976-9102(ONLINE)                                                                                       ICTACT JOURNAL ON IMAGE AND VIDEO PROCESSING, NOVEMBER 2014, VOLUME: 05, ISSUE: 02 933 coefficients such that 2n ≤ | c(i, j) | ≤ 2n+1, with n being decremented at each pass. This pass divides the pixels into  partitioning  subsets  and  then  tests  each  of  these subsets  for  significant  pixels.  On  finding  that  some pixels in the subset are significant, sorting pass divides subset into smaller subsets. This process continues until all the pixels in that subset are tested for significance. Step 3: Refinement pass.   In refinement pass, the nth MSB of all the coefficients found to be significant  when compared  with 2n+1 are transmitted. These bits are transmitted in the same order as  used  to  transmit  the  significance  map  during  the sorting pass. Step 4: Quantization-step update.   Decrement n by 1 and the procedure is repeated from step 2 onwards. 3. EXPERIMENT METHOD The  Fig.1  shows  the  steps  involved.  The  experiment  is conducted using MATLAB image processing tool. The color image used is the standard lena image, a 24 bit 256 × 256 .jpg image. The RGB color image is converted into YCbCr format. DWT is applied to each of YCbCr components. SPIHT algorithm is then applied to encode the DWT coefficients. A compressed image is created after this step. Entropy coding is avoided at this step for simplicity. In the next phase of decoding to obtain the reconstructed image, decoding is performed using SPIHT algorithm and inverse DWT is applied. YCbCr  is  later  converted  to  RGB  image.  This  experiment  is repeated for different wavelet types and a range of coefficients for each of the wavelet types.  Fig.1. Color image processing using SPIHT algorithm The  performance  is  evaluated  using  PSNR,  CR  and  HVP. For  calculating  PSNR,  only  Y  (luminance)  component  of original and reconstructed image is used. Lena image shown in Fig.2  is  used  for  our  analysis.  For  computing  HVP,  ten individuals are asked to rate the quality of image on a scale of 1 to 5. The average of the rating of ten individuals is the HVP of that image.  Fig.2. Lena image 4. PERFORMANCE ANALYSIS PARAMETERS We  have  used  four  different  parameters  to  compare performance  of  the  SPIHT  algorithm  in  different  wavelet families. The simplest and most widely used objective quality metric is the mean squared error (MSE), computed by averaging the  squared  intensity  differences  of  distorted  and  reference image pixels, along with the related quantity of peak signal-to-noise  ratio  (PSNR).  We  have  used  human  visual  perception (HVP) to evaluate the performance subjectively.  The MSE (mean square error) is          255025502 , ,256 2561x yy x f y x h MSE   (2) where,  h(x,  y)  is  the  original  image  matrix  and  f(x,  y)  is  the reconstructed image matrix. The PSNR is defined as,     MSEMAXPSNR I10 log 20   (3) where, MAX I is the size of the image. The  amount  of  compression  achieved  is  measured  by  the compression ratio (CR) defined as,  image   compressed   the   in   bits   of   Numberimage   original   the   in   bits   of   number   TotalCR    (4) The HVP is evaluated by asking the individuals to identify the similarity between original and reconstructed images on a scale of 1 to 5.  5. RESULTS A  consistent  method  involving  six  steps  was  followed  for performance analysis.  Start Load color(RGB) image RGB image to YcbCr image conversion Apply DWT to YcbCr components of the image Apply SPIHT Algorithm Decode using SPIHT Algorithm Apply Inverse DWT Convert YcbCr image into RGB image Compressed image Reconstructed image A SREENIVASA MURTHY et al.: PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION 934 5.1  PERFORMANCE ANALYSIS STEPS i.  For the lena image, execute the algorithm by iterating over  a  range  of  wavelet  coefficients  for  the  chosen wavelet type.  ii.  Plot PSNR and CR for the results obtained in step 1. iii.  Obtain  the  optimal  wavelet  coefficient.  The  optimal wavelet coefficient is one which has the highest CR and the corresponding PSNR. If the highest CR is the same for  more  than  one  coefficient,  then  choose  the coefficient with the highest among the multiple highest CR.  iv.  Repeat step 1, 2 and 3 for multiple family of wavelets. Fig.3 to Fig.7 depicts the charts used to determine the optimum  wavelet  coefficients  for  the  chosen  wavelet types. v.  Plot  the  PSNR  and  CR  for  each  of  the  optimal coefficients determined from steps 1 to 4. vi.  From the plot in step 5, determine the best wavelet(s) and their corresponding coefficients. The  results  are  summarized  in  Table.1.  For  Daubechies, variation in CR and PSNR were negligible from db16 to db45 hence they were ignored Similarly, for Symlet, the coefficients from sym17 to sym37 were ignored.  Table.1. Summary of results Wavelet = DB  db1  db2  db3  db4  db5  db6  db7  db8  db9  db10  db11  db12  db13  db14  db15 PSNR(db)  39.53  40.68  41.03  41.15  41.12  40.98  41.09  40.78  40.77  40.78  40.47  40.49  40.37  40.16  40.25 CR  1.82  1.09  1.08  1.074  1.067  1.0596  1.0596  1.053  1.046  1.053  1.0389  1.046  1.04  1.04  1.03 Wavelet = COIFLET  coif1  coif2  coif3  coif4  coif5                     PSNR(db)  40.82  41.31  41.36  41.28  41.23                     CR  1.09  1.09  1.08  1.074  1.067                     Wavelet = SYMLET  sym2  sym3  sym4  sym5  sym6  sym7  sym8  sym9  sym10  sym11  sym12  sym13  sym14  sym15  sym16 PSNR(db)  40.68  41.03  41.27  41.34  41.4  41.32  41.4  41.38  41.32  41.25  41.34  41.32  41.35  41.26  41.33 CR  1.09  1.08  1.08  1.09  1.074  1.074  1.074  1.074  1.067  1.067  1.067  1.067  1.059  1.059  1.059 Wavelet = BIOR  bior1.1 bior1.3 bior1.5 bior2.2 bior2.4 bior2.6  bior2.8 bior3.1 bior3.3  bior3.5  bior3.7  bior3.9  bior4.4  bior5.5  bior6.8 PSNR(db)  39.53  39.12  38.84  41.21  41.19  41.1  40.97  37.87  39.37  39.66  39.72  39.75  41.58  40.64  41.6 CR  1.84  1.7  1.67  1.11  1.103  1.095  1.095  1.0596  1.08  1.08  1.08  1.08  1.0958  1.067  1.088 Wavelet = RBIO  rbio1.1 rbio1.3 rbio1.5 rbio2.2 rbio2.4 rbio2.6  rbio2.8 rbio3.1 rbio3.3  rbio3.5  rbio3.7  rbio3.9  rbio4.4  rbio5.5  rbio6.8 PSNR(db)  39.53  41.16  41.09  38.05  39.45  39.69  39.74  28.86  34.01  36.09  36.79  36.97  40.54  40.5  40.95 CR  1.82  1.103  1.088  1.019  1.039  1.039  1.039  0.869  0.96  0.988  0.994  0.994  1.066  1.081  1.06 Wavelet = DMEY  dmey                             PSNR(db)  41.11                             CR  1.05                              Fig.3. Optimum Daubechies (db) wavelet coefficient  Fig.4. Optimum Coiflet (coif) wavelet coefficient 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 38 38.5 39 39.5 40 40.5 41 41.5 db1 db3 db5 db7 db9 db11 db13 db15 db17 db19 db21 db23 db25 db27 CR PSNR in db Daubechies   PSNR (db) CR For db1: PSNR  is 39.53db  and  CR is 1.84 1.055 1.06 1.065 1.07 1.075 1.08 1.085 1.09 1.095 40.5 40.6 40.7 40.8 40.9 41 41.1 41.2 41.3 41.4 41.5 coif1  coif2  coif3  coif4  coif5 CR PSNR in db Coiflet  PSNR (db) CR For  coif2: PSNR  is 41.3db  and CR  is 1.09 ISSN: 0976-9102(ONLINE)                                                                                       ICTACT JOURNAL ON IMAGE AND VIDEO PROCESSING, NOVEMBER 2014, VOLUME: 05, ISSUE: 02 935  Fig.5. Optimum Symlet (sym) wavelet coefficient  Fig.6. Optimum Bi-Orthogonal (bior) wavelet coefficient     Fig.7. Optimum Reverse Bi-Orthogonal (rbio) wavelet coefficient  Fig.8. Determination of optimal performing wavelet In Fig.3 to Fig.8, the PSNR is plotted as discrete values and CR as continuous values. The optimum wavelet coefficient for each wavelet type is determined from Fig.3 to Fig.7. The results are summarized in Table.2. Fig.8 is a plot of Table.2. From the Fig.8, it can be observed that the best performance is obtained for db1and bior1.1. Table.2. Optimum wavelets coefficients Wavelet Coefficient  db1  coif2 sym5 bior1.1 rbio1.1 dmey PSNR  39.53 41.31 41.34  39.53  39.53  41.1 CR  1.84  1.09  1.09  1.84  1.82  1.05 5.2  OBSERVATION Daubechies wavelet with coefficient db1 and Bi-Orthogonal with  coefficient  bior1.1  perform  well  on  compression  using SPIHT algorithm. For db1, a CR of 1.84 with PSNR of 39.53db is observed. For bior1.1, a CR of 1.84 with PSNR of 39.53db is observed. The Fig.9 and Fig.10 shows the results obtained by applying  Daubechies  (db1)  and  Bi-Orthogonal  (bior1.1) wavelets to the original lena image.    Original Image   Reconstructed Image Fig.9. Lena compressed image obtained by applying db1 wavelet    Original Image   Reconstructed Image Fig.10. Lena compressed image obtained by applying bior1.1 wavelet 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.1 40.2 40.4 40.6 40.8 41 41.2 41.4 41.6 CR PSNR in db Symlet  PSNR (db) CR For sym5: PSNR is 41.34db and CR  is 1.09 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 36 37 38 39 40 41 42 bior1.1 bior1.3 bior1.5 bior2.2 bior2.4 bior2.6 bior2.8 bior3.1 bior3.3 bior3.5 bior3.7 bior3.9 bior4.4 bior5.5 bior6.8 CR PSNR in db Bi-Orthogonal  PSNR (db) CR For bior1.1: PSNR  is 39.53db  and  CR  is 1.84 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 0 5 10 15 20 25 30 35 40 45 rbio1.1 rbio1.3 rbio1.5 rbio2.2 rbio2.4 rbio2.6 rbio2.8 rbio3.1 rbio3.3 rbio3.5 rbio3.7 rbio3.9 rbio4.4 rbio5.5 rbio6.8 CR PSNR in db  Reverse Bi-Orthogonal  PSNR (db) CR  For rbio1.1: PSNR is 39.53 db and CR  is 1.82 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 38.5 39 39.5 40 40.5 41 41.5 db1  coif2  sym5  bior1.1  rbio1.1  dmey CR PSNR in db Wavelet type and optimal coefficient Wavelet families analysis for compression PSNR CR A SREENIVASA MURTHY et al.: PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION 936 5.3  QUALITATIVE ASSESSMENT – TABULATION OF RESULTS  The reconstructed images chosen are obtained by applying Daubechies wavelet (db1) and Bi-Orthogonal wavelet (bior1.1) to the original image. Here original and reconstructed images are shown  to  ten  individuals  i.e.,  I1  to  I10  and  asked  to  rate similarity between original and reconstructed images in a scale of 1 to 5. The average of ten individual’s ratings is calculated. Table.3 lists the HVP rating. Table.3. HVP rating Individuals  l1  l2  l3  l4  l5  l6  l7  l8  l9  l10 Rating-db1  4.9  4.8  4.7  4.8  4.7  4.7  4.7  4.9  4.9  4.9 Rating-bior1.1  4.8  4.9  4.8  4.7  4.8  4.7  4.8  4.9  4.9  4.9 Average rating, db1  4.8   Average rating, bior1.1  4.82 6. CONCLUSION The most optimal performance of the algorithm is observed for Daubechies wavelet with coefficient db1 and Bi-orthogonal wavelet with coefficient bior1.1. A CR of 1.84 is observed at a PSNR of 39.53db for Daubechies wavelet (db1 coefficient) and CR of 1.84 with PSNR of 39.53db for Bi-Orthogonal (bior1.1 coefficient) wavelet. 7. FUTURE WORK In this experiment a Lena JPEG image is considered for the analysis since the image has a moderate spectral activity. The experiment  can  be  conducted  for  other  standard  images  like cameraman,  Zebra  etc  with  varying  spectral  activity.    The experiment was conducted on a low resolution image [24 bit 256 × 256]. This can be extended to high resolution images.      REFERENCES [1]  Said A and Pearlman WA, “A new fast and efficient image codec based on set partitioning in hierarchical trees”, IEEE Transactions  on  Circuits  and  Systems  for  Video Technology, pp. 243-250, 1996. [2]  Raghuveer  M.  rao  and  Ajith  S  Bobardikar,  “Wavelet Transforms:  Introduction  to  Theory  and  Applications”, Addison-Wesley, Vol. 1, 1998. [3]  Daubechies,  “Ten  Lectures  on  Wavelets”,  Society  for Industrial and Applied Mathematics, 1992. [4]  A. S. Lewis and G. Knowles, “Image compression using the 2-D wavelet transform”, IEEE Transactions on Image Processing, Vol. 1, No. 2, pp. 244-250,1992.  [5]  Sonja  Grgic,  Mislav  Grgic  and  Branka  Zovko-Cihlar, “Performance  Analysis  of  Image  Compression  Using Wavelets”,  IEEE  Transactions  on  Industrial  Electronics, Vol. 48, No. 3, pp. 682-695, 2001. [6]  J. Oliver and M. P. Malumbres, “An implementation of the EZW  algorithm”,  Universidad  Polit_ecnica  de  Valencia, DISCA Department, 2001. [7]  William  A.  Pearlman  and  Amir  Said,  “Set  Partition Coding: Part I and II of Set Partition Coding and Image Wavelet  Coding  Systems”,  Foundations  and  Trends  in Signal Processing, Vol. 2, No. 2, pp. 95-180, 2008. [8]  Z.  Xiang,  K.  Ramchandran,  M.  T.  Orchard  and  Y.  Q. Zhang, “A comparative study of DCT and wavelet-based image coding”, IEEE Transactions on Circuits and Systems for Video Technology, Vol. 9, No. 5, pp.  692-695,1999. [9]  ISO/IEC, “Digital Compression and Coding Of Continuous Tone Still Images”, Part 1 and 2, 1991. [10] International  Telecommunication  Union,  “Information Technology  -  Generic,  Coding  Of  Moving  Pictures  and Associated  Audio  Information:  Video”,  Recommendation H.262, 1994. [11] K.  R.  Rao  and  P.  Yip,  “Discrete  Cosine  Transform: Algorithms,  Advantages  and  Applications”,  Academic Press, 1990. [12] Yogendra  Kumar  Jain  and  Sanjeev  Jain,  “Performance Analysis  and  Comparison  of  Wavelet Families  Using  for Image  Compression”,  International  Journal  of  Soft Computing, Vol.  2, No. 1, pp. 161-171, 2007.  

PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION

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A SREENIVASA MURTHY et al.: PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION 932 PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION A. Sreenivasa Murthy1, K.N. Ramesh2 and Y.A. Mamatha3 Department of Electronics and Communication Engineering, Bangalore University, India E-mail: 1uvceasm@gmail.com, 2rkestur@gmail.com, 3mamatha.ya52@gmail.comAbstract With the spurt in the amount of data (Image, video, audio, speech, & text) available on the net, there is a huge demand for memory & bandwidth savings. One has to achieve this, by maintaining the quality & fidelity of the data acceptable to the end user. Wavelet transform is an important and practical tool for data compression. Set partitioning in hierarchal trees (SPIHT) is a widely used compression algorithm for wavelet transformed images. Among all wavelet transform and zero-tree quantization based image compression algorithms SPIHT has become the benchmark state-of-the-art algorithm because it is simple to implement & yields good results. In this paper we present a comparative study of various wavelet families for image compression with SPIHT algorithm. We have conducted experiments with Daubechies, Coiflet, Symlet, Bi-orthogonal, Reverse Bi-orthogonal and Demeyer wavelet types. The resulting image quality is measured objectively, using peak signal-to-noise ratio (PSNR), and subjectively, using perceived image quality (human visual perception, HVP for short). The resulting reduction in the image size is quantified by compression ratio (CR).  Keywords:  SPIHT, DWT, Image Compression 1. INTRODUCTION  Social networking and the always connected personal digital assistants (PDA) and more popularly called the smart phones paradigm have made a transformational impact on the real social lives of the connected world. As a consequence there is a huge burst in demand for image storage and transmission. Images and videos are uploaded and downloaded anytime, anywhere. Image storage and transmission is resource intensive, in such a scenario it is imperative to optimize storage and transmission bandwidth. Current popular method of compression is DCT [9],[10]. DCT based compression represents image as a superposition of cosine functions of different frequencies [11]. DCT is characterized by high speed and low cost and hence popular. DCT uses uniform sized square block size which reduces the complexity of compression. The uniform block size does not factor the irregular shape within the uniform block. This is the fundamental drawback of DCT which is known as blocking effect. Wavelets are extensively used due to their portability for image processing and particularly in image compression. Wavelets works on the principle of hierarchically decomposing an image into successful lower resolution components and their associated detailed components. At each level, the reference and detailed components contain the information required to reconstruct the reference component at the next higher resolution level. Wavelet provide good compression ratios and performed better when compared to popular techniques like JPEG in terms of signal to noise ratio and image quality. Unlike JPEG, it does not have blocking effect and allows for seamless degradation of the whole image quality. However the implementation complexity of wavelet based compression is higher than DCT. A study of the performance difference of the discrete cosine transform (DCT) and the wavelet transform for both image and video coding, was studied in the paper by Xiang et.al [8]. Performance analysis and comparison of wavelet families using for image compression of different images was studied in the paper [12]. This work attempts to perform an analysis of family of wavelets with the SPIHT algorithm for image compression. Wavelet [2],[3] is a small wave of limited duration, localized in time and scale and has an average value of zero. In recent times, much of the research activities in image coding have been focused on the discrete wavelet transform (DWT), which has become a standard tool in image compression applications because of their data reduction capability, low computational complexity, & possibility of constructing their own basis function [4],[5],[8]. In this paper, Daubechies, Coiflet, Symlet, Bi-orthogonal, Reverse Bi-orthogonal and Demeyer wavelet types are considered for image compression using SPIHT algorithm. Of most algorithms developed, SPIHT algorithm is treated as one of the most significant among these algorithms because it’s fully embedded codec, optimized for progressive image transmission and provides good quality image and coding efficiency.  2. SPIHT ALGORITHM  SPIHT [7] was introduced by Said and Pearlman. The SPIHT algorithm is a highly refined version of the EZW [6] algorithm. The wavelet based SPIHT algorithm involves coding of the wavelet transform of an image by set partitioning along spatial orientation trees and progressive bit-plane coding of significant coefficients. The steps involved in the SPIHT algorithm are: Step 1: Initialization.   The value of n is calculated to set threshold 2n using the equation      jicn ,2 maxlog  (1)  where, ci,j is the wavelet coefficient at co-ordinate (i, j). Three lists such as LSP (list of significant pixels), LIP (list of insignificant pixels) and LIS (list of insignificant set) are constructed. LSP is initialized as an empty set. LIP is initialized to contain all pixels in low pass sub band. LIS is initialized to contain all pixels in low pass sub band that have descendants and forms roots of spatial tree. Step 2: Sorting pass.   The sorting pass is made for the first threshold. This pass involves checking the data several times and selecting ISSN: 0976-9102(ONLINE)                                                                                       ICTACT JOURNAL ON IMAGE AND VIDEO PROCESSING, NOVEMBER 2014, VOLUME: 05, ISSUE: 02 933 coefficients such that 2n ≤ | c(i, j) | ≤ 2n+1, with n being decremented at each pass. This pass divides the pixels into partitioning subsets and then tests each of these subsets for significant pixels. On finding that some pixels in the subset are significant, sorting pass divides subset into smaller subsets. This process continues until all the pixels in that subset are tested for significance. Step 3: Refinement pass.  In refinement pass, the nth MSB of all the coefficients found to be significant when compared with 2n+1 are transmitted. These bits are transmitted in the same order as used to transmit the significance map during the sorting pass. Step 4: Quantization-step update.  Decrement n by 1 and the procedure is repeated from step 2 onwards. 3. EXPERIMENT METHOD The Fig.1 shows the steps involved. The experiment is conducted using MATLAB image processing tool. The color image used is the standard lena image, a 24 bit 256 × 256 .jpg image. The RGB color image is converted into YCbCr format. DWT is applied to each of YCbCr components. SPIHT algorithm is then applied to encode the DWT coefficients. A compressed image is created after this step. Entropy coding is avoided at this step for simplicity. In the next phase of decoding to obtain the reconstructed image, decoding is performed using SPIHT algorithm and inverse DWT is applied. YCbCr is later converted to RGB image. This experiment is repeated for different wavelet types and a range of coefficients for each of the wavelet types.  Fig.1. Color image processing using SPIHT algorithm The performance is evaluated using PSNR, CR and HVP. For calculating PSNR, only Y (luminance) component of original and reconstructed image is used. Lena image shown in Fig.2 is used for our analysis. For computing HVP, ten individuals are asked to rate the quality of image on a scale of 1 to 5. The average of the rating of ten individuals is the HVP of that image.  Fig.2. Lena image 4. PERFORMANCE ANALYSIS PARAMETERS We have used four different parameters to compare performance of the SPIHT algorithm in different wavelet families. The simplest and most widely used objective quality metric is the mean squared error (MSE), computed by averaging the squared intensity differences of distorted and reference image pixels, along with the related quantity of peak signal-to-noise ratio (PSNR). We have used human visual perception (HVP) to evaluate the performance subjectively.  The MSE (mean square error) is        255025502,,2562561x yyxfyxhMSE  (2) where, h(x, y) is the original image matrix and f(x, y) is the reconstructed image matrix. The PSNR is defined as,  MSEMAXPSNR I10log20  (3) where, MAX I is the size of the image. The amount of compression achieved is measured by the compression ratio (CR) defined as,  image compressed the in bits of Numberimage original the in bits of number TotalCR   (4) The HVP is evaluated by asking the individuals to identify the similarity between original and reconstructed images on a scale of 1 to 5.  5. RESULTS A consistent method involving six steps was followed for performance analysis.  Start Load color(RGB) image RGB image to YcbCr image conversion Apply DWT to YcbCr components of the image Apply SPIHT Algorithm Decode using SPIHT Algorithm Apply Inverse DWT Convert YcbCr image into RGB image Compressed image Reconstructed image A SREENIVASA MURTHY et al.: PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION 934 5.1 PERFORMANCE ANALYSIS STEPS i. For the lena image, execute the algorithm by iterating over a range of wavelet coefficients for the chosen wavelet type.  ii. Plot PSNR and CR for the results obtained in step 1. iii. Obtain the optimal wavelet coefficient. The optimal wavelet coefficient is one which has the highest CR and the corresponding PSNR. If the highest CR is the same for more than one coefficient, then choose the coefficient with the highest among the multiple highest CR.  iv. Repeat step 1, 2 and 3 for multiple family of wavelets. Fig.3 to Fig.7 depicts the charts used to determine the optimum wavelet coefficients for the chosen wavelet types. v. Plot the PSNR and CR for each of the optimal coefficients determined from steps 1 to 4. vi. From the plot in step 5, determine the best wavelet(s) and their corresponding coefficients. The results are summarized in Table.1. For Daubechies, variation in CR and PSNR were negligible from db16 to db45 hence they were ignored Similarly, for Symlet, the coefficients from sym17 to sym37 were ignored.  Table.1. Summary of results Wavelet = DB db1 db2 db3 db4 db5 db6 db7 db8 db9 db10 db11 db12 db13 db14 db15 PSNR(db) 39.53 40.68 41.03 41.15 41.12 40.98 41.09 40.78 40.77 40.78 40.47 40.49 40.37 40.16 40.25 CR 1.82 1.09 1.08 1.074 1.067 1.0596 1.0596 1.053 1.046 1.053 1.0389 1.046 1.04 1.04 1.03 Wavelet = COIFLET coif1 coif2 coif3 coif4 coif5           PSNR(db) 40.82 41.31 41.36 41.28 41.23           CR 1.09 1.09 1.08 1.074 1.067           Wavelet = SYMLET sym2 sym3 sym4 sym5 sym6 sym7 sym8 sym9 sym10 sym11 sym12 sym13 sym14 sym15 sym16 PSNR(db) 40.68 41.03 41.27 41.34 41.4 41.32 41.4 41.38 41.32 41.25 41.34 41.32 41.35 41.26 41.33 CR 1.09 1.08 1.08 1.09 1.074 1.074 1.074 1.074 1.067 1.067 1.067 1.067 1.059 1.059 1.059 Wavelet = BIOR bior1.1 bior1.3 bior1.5 bior2.2 bior2.4 bior2.6 bior2.8 bior3.1 bior3.3 bior3.5 bior3.7 bior3.9 bior4.4 bior5.5 bior6.8 PSNR(db) 39.53 39.12 38.84 41.21 41.19 41.1 40.97 37.87 39.37 39.66 39.72 39.75 41.58 40.64 41.6 CR 1.84 1.7 1.67 1.11 1.103 1.095 1.095 1.0596 1.08 1.08 1.08 1.08 1.0958 1.067 1.088 Wavelet = RBIO rbio1.1 rbio1.3 rbio1.5 rbio2.2 rbio2.4 rbio2.6 rbio2.8 rbio3.1 rbio3.3 rbio3.5 rbio3.7 rbio3.9 rbio4.4 rbio5.5 rbio6.8 PSNR(db) 39.53 41.16 41.09 38.05 39.45 39.69 39.74 28.86 34.01 36.09 36.79 36.97 40.54 40.5 40.95 CR 1.82 1.103 1.088 1.019 1.039 1.039 1.039 0.869 0.96 0.988 0.994 0.994 1.066 1.081 1.06 Wavelet = DMEY dmey               PSNR(db) 41.11               CR 1.05                Fig.3. Optimum Daubechies (db) wavelet coefficient  Fig.4. Optimum Coiflet (coif) wavelet coefficient 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 38 38.5 39 39.5 40 40.5 41 41.5 db1 db3 db5 db7 db9 db11 db13 db15 db17 db19 db21 db23 db25 db27 CR PSNR in db Daubechies  PSNR (db) CR For db1: PSNR is 39.53db  and CR is 1.84 1.055 1.06 1.065 1.07 1.075 1.08 1.085 1.09 1.095 40.5 40.6 40.7 40.8 40.9 41 41.1 41.2 41.3 41.4 41.5 coif1 coif2 coif3 coif4 coif5 CR PSNR in db Coiflet PSNR (db) CR For coif2: PSNR is 41.3db and CR  is 1.09 ISSN: 0976-9102(ONLINE)                                                                                       ICTACT JOURNAL ON IMAGE AND VIDEO PROCESSING, NOVEMBER 2014, VOLUME: 05, ISSUE: 02 935  Fig.5. Optimum Symlet (sym) wavelet coefficient  Fig.6. Optimum Bi-Orthogonal (bior) wavelet coefficient     Fig.7. Optimum Reverse Bi-Orthogonal (rbio) wavelet coefficient  Fig.8. Determination of optimal performing wavelet In Fig.3 to Fig.8, the PSNR is plotted as discrete values and CR as continuous values. The optimum wavelet coefficient for each wavelet type is determined from Fig.3 to Fig.7. The results are summarized in Table.2. Fig.8 is a plot of Table.2. From the Fig.8, it can be observed that the best performance is obtained for db1and bior1.1. Table.2. Optimum wavelets coefficients Wavelet Coefficient db1 coif2 sym5 bior1.1 rbio1.1 dmey PSNR 39.53 41.31 41.34 39.53 39.53 41.1 CR 1.84 1.09 1.09 1.84 1.82 1.05 5.2 OBSERVATION Daubechies wavelet with coefficient db1 and Bi-Orthogonal with coefficient bior1.1 perform well on compression using SPIHT algorithm. For db1, a CR of 1.84 with PSNR of 39.53db is observed. For bior1.1, a CR of 1.84 with PSNR of 39.53db is observed. The Fig.9 and Fig.10 shows the results obtained by applying Daubechies (db1) and Bi-Orthogonal (bior1.1) wavelets to the original lena image.   Original Image  Reconstructed Image Fig.9. Lena compressed image obtained by applying db1 wavelet   Original Image  Reconstructed Image Fig.10. Lena compressed image obtained by applying bior1.1 wavelet 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.1 40.2 40.4 40.6 40.8 41 41.2 41.4 41.6 CR PSNR in db Symlet PSNR (db) CR For sym5: PSNR is 41.34db and CR  is 1.09 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 36 37 38 39 40 41 42 bior1.1 bior1.3 bior1.5 bior2.2 bior2.4 bior2.6 bior2.8 bior3.1 bior3.3 bior3.5 bior3.7 bior3.9 bior4.4 bior5.5 bior6.8 CR PSNR in db Bi-Orthogonal PSNR (db) CR For bior1.1: PSNR is 39.53db  and CR is 1.84 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 0 5 10 15 20 25 30 35 40 45 rbio1.1 rbio1.3 rbio1.5 rbio2.2 rbio2.4 rbio2.6 rbio2.8 rbio3.1 rbio3.3 rbio3.5 rbio3.7 rbio3.9 rbio4.4 rbio5.5 rbio6.8 CR PSNR in db  Reverse Bi-Orthogonal PSNR (db) CR For rbio1.1: PSNR is 39.53 db and CR  is 1.82 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 38.5 39 39.5 40 40.5 41 41.5 db1 coif2 sym5 bior1.1 rbio1.1 dmey CR PSNR in db Wavelet type and optimal coefficient Wavelet families analysis for compression PSNR CR A SREENIVASA MURTHY et al.: PERFORMANCE ANALYSIS OF SET PARTITIONING IN HIERARCHICAL TREES (SPIHT) ALGORITHM FOR A FAMILY OF WAVELETS USED IN COLOR IMAGE COMPRESSION 936 5.3 QUALITATIVE ASSESSMENT – TABULATION OF RESULTS  The reconstructed images chosen are obtained by applying Daubechies wavelet (db1) and Bi-Orthogonal wavelet (bior1.1) to the original image. Here original and reconstructed images are shown to ten individuals i.e., I1 to I10 and asked to rate similarity between original and reconstructed images in a scale of 1 to 5. The average of ten individual’s ratings is calculated. Table.3 lists the HVP rating. Table.3. HVP rating Individuals l1 l2 l3 l4 l5 l6 l7 l8 l9 l10 Rating-db1 4.9 4.8 4.7 4.8 4.7 4.7 4.7 4.9 4.9 4.9 Rating-bior1.1 4.8 4.9 4.8 4.7 4.8 4.7 4.8 4.9 4.9 4.9 Average rating, db1 4.8  Average rating, bior1.1 4.82 6. CONCLUSION The most optimal performance of the algorithm is observed for Daubechies wavelet with coefficient db1 and Bi-orthogonal wavelet with coefficient bior1.1. A CR of 1.84 is observed at a PSNR of 39.53db for Daubechies wavelet (db1 coefficient) and CR of 1.84 with PSNR of 39.53db for Bi-Orthogonal (bior1.1 coefficient) wavelet. 7. FUTURE WORK In this experiment a Lena JPEG image is considered for the analysis since the image has a moderate spectral activity. 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Performance Analysis of Set Partitioning in Hierarchical Trees (spiht) Algorithm for a Family of Wavelets Used in Color Image Compression

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