Lossy Compression of Stochastic Halftones with JBIG2 - PowerPoint PPT Presentation

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Lossy Compression of Stochastic Halftones with JBIG2

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Lossy Compression of Stochastic Halftones with JBIG2 Magesh Valliappan and Brian L. Evans Embedded Signal Processing Laboratory The University of Texas at Austin – PowerPoint PPT presentation

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Title: Lossy Compression of Stochastic Halftones with JBIG2


1
Lossy Compression ofStochastic Halftones with
JBIG2
  • Magesh Valliappan and Brian L. Evans
  • Embedded Signal Processing Laboratory
  • The University of Texas at Austin
  • http//signal.ece.utexas.edu/

Dave A. D. Tompkins and Faouzi Kossentini Signal
Processing and Multimedia Group University of
British Columbia http//spmg.ece.ubc.ca
2
Introduction
  • Digital halftoning
  • Continuous tone to bi-level
  • Ordered dithered halftones
  • Periodic mask of thresholds
  • Stochastic halftones
  • Shape quantization noise intohigh frequencies

3
Joint Bi-Level Experts Group
  • JBIG2 Standard
  • Document printing, faxing, scanning, storage
  • Lossy and lossless coding
  • Models for text, halftone, and generic regions
  • Lossy JBIG2 compression of halftones
  • Preserve local average gray level not halftone
  • Spatially periodic descreening
  • High compression of ordered dither halftones

4
Motivation
  • Improve JBIG2 performance on stochastic halftones

Existing JBIG-26.1 1
Proposed Method 6.6 1
5
Lossy Compression of Halftones
Generate (M21) patterns ofsize M x M from a
clustereddot threshold mask
Construct Pattern Dictionary
Lossless Encoder
JBIG2 bitstream
Halftone
Compute Indices into Dictionary
Count black dots in each M x M block of
input Range of indices 0... M21
6
Proposed Method
  • modified multilevel Floyd Steinberg error
    diffusion
  • optionally reduce N
  • L sharpening factor
  • one multiply/add
  • 3 x 3 lowpass
  • zeros at Nyquist
  • removes noise
  • artifacts
  • power-of-two coefficients

Prefilter
Decimator
Quantizer
Lossless Encoder
JBIG2 bitstream
Halftone
17
16 M2 1
graylevels
N
2
  • M x M lowpass averaging filter
  • downsample by M x M

Symbol Dictionary
  • N patterns
  • size M x M
  • may be angled
  • clustered dot

7
Quality Metrics
  • Model degradation as linear filter plus noise
  • Decouple and quantify linear and additive effects
  • Contrast sensitivity function (CSF) C(?1, ?2)
  • Linear shift-invariant model of human visual
    system
  • Weighting of distortion measures in frequency
    domain

8
Quality Metrics
  • Estimate linear model by Wiener filter
  • Weighted Signal to Noise Ratio (WSNR)
  • Weight noise D(u , v) by CSF C(u , v)
  • Linear Distortion Measure
  • Weight distortion by input spectrum X(u , v) and
    CSF C(u , v)

9
Results
High Quality Ratio 6.6 1 WSNR 18.7 dB LDM 0.116
High Compression Ratio 9.9 1 WSNR 14.0
dB LDM 0.158
512 x 512 Floyd Steinberg halftoneof barbara
image
10
Results
Results for 512 512 Floyd Steinberg halftone
11
Rate Distortion Curve - LDM
12
Rate Distortion Curve - WSNR
13
Conclusions
  • JBIG2 encoding of stochastic halftones
  • Reduce noise and artifacts
  • Achieve higher compression ratios
  • Require low computational complexity
  • Rate distortion tradeoffs of free parameters
  • Quality metrics consistent with visual quality

14
Backup Slides
15
Introduction
  • Compression of halftones
  • Document printing, faxing, scanning, storage
  • 4" 4" 600dpi halftone (1bpp), 720,000 bytes
  • Lossy compression
  • Details invisible to human eye
  • Only underlying grayscale image important
  • Perceptually near lossless at high compression

16
Standards
  • Group 3 fax standard (1980)
  • 1-D data model
  • lossless run length encoding and Huffman encoding
  • Group 4 fax standard (1985)
  • 2-D data model
  • Joint bi-level experts group 1 (1995)
  • 2-D lossless context based arithmetic coding
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