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DCT

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Down-sample by factors of 2 in each dimension, e.g., reduce 640 x 480 to 320 x 240 ... Din. Reset. Clk. Naghmeh Karimi; Tehran University. 48. Timing Diagram ... – PowerPoint PPT presentation

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Title: DCT


1
DCT
  • By Naghmeh Karimi
  • The material in this class presentation have been
    collected from different published works of other
    authors and are presented here for educational
    purposes only.
  • Under supervision of
  • Dr. Fakhraie
  • University of Tehran

2
Outline
  • Introduction
  • JPEG coding
  • DCT technique

3
Introduction
4
JPEG Coding
  • Lossy
  • Lossless

5
Lossless Compression
Source image data
Compressed image data
Predictor
Entropy Coder
Entropy_Table Specifications
6
Lossy Compression
  • Baseline sequential mode compression
  • Progressive mode
  • Hierarchical mode

7
Baseline Sequential mode
  • An image is partitioned into some 8 by 8
    non-overlapping pixel blocks from left to right
    and top to bottom.
  • Each block is coded individually.

8
Progressive mode
  • Start with a low quality image and successively
    improve.
  • Spectral selection Send DC component and first
    few AC coefficients first, then gradually some
    more ACs.
  • 2. Successive approximation send DCT
    coefficients MSB (most significant bit) to LSB
    (least significant bit).

9
Hierarchical mode
  • Down-sample by factors of 2 in each dimension,
    e.g., reduce 640 x 480 to 320 x 240
  • 2. Code smaller image using another JPEG mode
    (Progressive, Sequential, or Lossless)
  • 3. Decode and up-sample encoded image
  • 4. Encode difference between the up-sampled and
    the original using Progressive,Sequential, or
    Lossless.

10
Hierarchical mode
  • An image is coded as a sequence of layers in a
    pyramid.
  • Except for the top level of pyramid, for each
    luminance and color component at the lower
    levels, the difference between the source
    components and the reference reconstructed image
    is coded.

11
Baseline JPEG Encoder(block diagram)
AC
Zigzag
VLC
Compressed image data
Q
Zero shift
DCT
VLC
Diff
DC
image
12
Color Transformation
  • The human visual systems is most sensitive to
    changes in luminance and less to changes in
    chrominance.
  • RGB must be converted to the other color systems
    .

13
YUV system
  • Y 0.299R 0.587G 0.114B
  • U B - Y
  • V R - Y

14
Zero Shift
  • After transformation Y, U and V are in the range
    of 0,255
  • Zero shift changes this range to -128,127

15
DCT
  • The strength of transform coding in achieving
    data compression is that the image energy of the
    most natural scenes is mainly concentrated in the
    low frequency region and hence into a few
    transform coefficients.

16
Quantization
  • Quantization allows us to reduce the accuracy
    with witch the DCT coefficients are represented
    when converting the DCT to an integer
    representation.
  • It tends to make many coefficients zero,
    specially those for high spatial frequencies.
  • Two standard table are available for quantization.

17
Zigzag Scan
  • The zigzag pattern used in the JPEG algorithms
    orders the basis functions from low to high
    spatial frequencies .
  • It facilitate entropy coding by encountering the
    most likely non-zero coefficient first.

18
Run Length Coding
  • For the JPEG standard, a symbol is structured in
    2 parts
  • Symbol1 (VLC)
  • Symbol2 binary representation of
    amplitude

19
Coding DC Coefficients
  • The differential rules are categorized based on
    the magnitude range called CAT.
  • The CAT is Variable Length Coded.

20
Coding AC Coefficients
  • For each non-zero AC coefficient in zigzag Scan
    symbol1 is described as a 2dimentional event of (
    Run, Cat ).
  • Cat category for the amplitude of a non-zero
    coefficient.
  • Run the number of zeros preceding this non-zero
    coefficient.

21
Coding AC Coefficients(Cont.)
  • If Run is greater than 15 then (Run, Cat) must be
    broken to some (15,0) followed by a (Cat1, Run1).
  • Example
  • (34,5) (15,0),(15,0),(2,5)
  • The end of the block is represented by (0,0)

22
Improving DCT Efficiency
  • Using LUTs .
  • Using FDCT Algorithms.
  • Using Pipeline structures.

23
Example
A
5 ? (3,3) ?111111110101101
24
2-DCT
25
First_Technique
  • 8-point DCT and IDCT
  • DCT
  • Input 8 bit
  • Output10 bit
  • IDCT
  • Input 10 bit
  • Output8 bit

26
8-point IDCT
27
8-point IDCT(Cont.)
28
Rotator
29
Rotator
  • Another Architecture with 3 adder and 3
    multiplier is possible.

30
8-point DCT
31
Rotator
32
Implementation Results
33
Second_Technique
34
1-D IDCT Equation Coefficients
Original Coefficients
Simplified Coefficients
35
Second_Technique
36
Total_Implementation
37
Wave-Forms
38
Results
39
Third_Technique(Pipeline)
40
Pipeline stages
41
Pipeline Structure
  • Each 1-D DCT stage 8 clk cycle
  • 1-D DCT architecture latency 48 clk cycle
  • The transpose buffer latency 64 clk cycle
  • Total160 clk cycle

42
Fourth_Technique
43
FDCT (cosine-factors)
44
Data flow graph for 8 point FDCT
45
Schematic of 2-D DCT
46
Schematic of transposition memory
47
Architecture and Operation of2-D DCT Circuit
Reset
Dout
Din
Clk
48
Timing Diagram for External In/Out Port
(A) Serial to Parallel conversion for
input (B)1-D DCT operation (C) Parallel to
Serial conversion for output
49
Functionality of internally generated control
signals
50
Row 1-D DCT Operation
Timing Diagram of Row 1-D DCT
51
Column 1-D DCT Operation
Timing Diagram between Row and Column 1-D DCT
52
Column 1-D DCT Operation (Cont.)
Timing Diagram of the last part of Column 1-D DCT
53
Fast_Multiplier
a
0
0
8a
2a
0
Multiplier
CSA
CSA
S
C
S
C
CSA
C
S
C
CSA
4
Sum
FF
4
Carry
54
Verilog-result(4-bit precision)
55
Matlab-result
56
  • Thank you!

List of References 1. 2. 3.
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