📄 synwtfilterfloatlift9x7.java
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/*
* CVS identifier:
*
* $Id: SynWTFilterFloatLift9x7.java,v 1.12 2000/12/12 16:54:24 grosbois Exp $
*
* Class: SynWTFilterFloatLift9x7
*
* Description: A synthetizing wavelet filter implementing the
* lifting 9x7 transform.
*
*
*
* COPYRIGHT:
*
* This software module was originally developed by Rapha雔 Grosbois and
* Diego Santa Cruz (Swiss Federal Institute of Technology-EPFL); Joel
* Askel鰂 (Ericsson Radio Systems AB); and Bertrand Berthelot, David
* Bouchard, F閘ix Henry, Gerard Mozelle and Patrice Onno (Canon Research
* Centre France S.A) in the course of development of the JPEG2000
* standard as specified by ISO/IEC 15444 (JPEG 2000 Standard). This
* software module is an implementation of a part of the JPEG 2000
* Standard. Swiss Federal Institute of Technology-EPFL, Ericsson Radio
* Systems AB and Canon Research Centre France S.A (collectively JJ2000
* Partners) agree not to assert against ISO/IEC and users of the JPEG
* 2000 Standard (Users) any of their rights under the copyright, not
* including other intellectual property rights, for this software module
* with respect to the usage by ISO/IEC and Users of this software module
* or modifications thereof for use in hardware or software products
* claiming conformance to the JPEG 2000 Standard. Those intending to use
* this software module in hardware or software products are advised that
* their use may infringe existing patents. The original developers of
* this software module, JJ2000 Partners and ISO/IEC assume no liability
* for use of this software module or modifications thereof. No license
* or right to this software module is granted for non JPEG 2000 Standard
* conforming products. JJ2000 Partners have full right to use this
* software module for his/her own purpose, assign or donate this
* software module to any third party and to inhibit third parties from
* using this software module for non JPEG 2000 Standard conforming
* products. This copyright notice must be included in all copies or
* derivative works of this software module.
*
* Copyright (c) 1999/2000 JJ2000 Partners.
* */
package jj2000.j2k.wavelet.synthesis;
import jj2000.j2k.wavelet.*;
import jj2000.j2k.image.*;
import jj2000.j2k.*;
/**
* This class inherits from the synthesis wavelet filter definition for int
* data. It implements the inverse wavelet transform specifically for the 9x7
* filter. The implementation is based on the lifting scheme.
*
* <P>See the SynWTFilter class for details such as normalization, how to
* split odd-length signals, etc. In particular, this method assumes that the
* low-pass coefficient is computed first.
*
* @see SynWTFilter
* @see SynWTFilterFloat
* */
public class SynWTFilterFloatLift9x7 extends SynWTFilterFloat {
/** The value of the first lifting step coefficient */
public final static float ALPHA = -1.586134342f;
/** The value of the second lifting step coefficient */
public final static float BETA = -0.05298011854f;
/** The value of the third lifting step coefficient */
public final static float GAMMA = 0.8829110762f;
/** The value of the fourth lifting step coefficient */
public final static float DELTA = 0.443568522f;
/** The value of the low-pass subband normalization factor */
public final static float KL = 0.8128930655f;//1.149604398f;
/** The value of the high-pass subband normalization factor */
public final static float KH = 1.230174106f;//0.8698644523f;
/**
* An implementation of the synthetize_lpf() method that works on int
* data, for the inverse 9x7 wavelet transform using the lifting
* scheme. See the general description of the synthetize_lpf() method in
* the SynWTFilter class for more details.
*
* <P>The low-pass and high-pass subbands are normalized by respectively a
* factor of 1/KL and a factor of 1/KH
*
* <P>The coefficients of the first lifting step are [-DELTA 1 -DELTA].
*
* <P>The coefficients of the second lifting step are [-GAMMA 1 -GAMMA].
*
* <P>The coefficients of the third lifting step are [-BETA 1 -BETA].
*
* <P>The coefficients of the fourth lifting step are [-ALPHA 1 -ALPHA].
*
* @param lowSig This is the array that contains the low-pass input
* signal.
*
* @param lowOff This is the index in lowSig of the first sample to
* filter.
*
* @param lowLen This is the number of samples in the low-pass input
* signal to filter.
*
* @param lowStep This is the step, or interleave factor, of the low-pass
* input signal samples in the lowSig array.
*
* @param highSig This is the array that contains the high-pass input
* signal.
*
* @param highOff This is the index in highSig of the first sample to
* filter.
*
* @param highLen This is the number of samples in the high-pass input
* signal to filter.
*
* @param highStep This is the step, or interleave factor, of the
* high-pass input signal samples in the highSig array.
*
* @param outSig This is the array where the output signal is placed. It
* should be long enough to contain the output signal.
*
* @param outOff This is the index in outSig of the element where to put
* the first output sample.
*
* @param outStep This is the step, or interleave factor, of the output
* samples in the outSig array.
*
* @see SynWTFilter#synthetize_lpf
* */
public
void synthetize_lpf(float[] lowSig, int lowOff, int lowLen, int lowStep,
float[] highSig, int highOff, int highLen, int highStep,
float[] outSig, int outOff, int outStep) {
int i;
int outLen = lowLen + highLen; //Length of the output signal
int iStep = 2*outStep; //Upsampling in outSig
int ik; //Indexing outSig
int lk; //Indexing lowSig
int hk; //Indexing highSig
// Generate intermediate low frequency subband
float sample = 0;
//Initialize counters
lk = lowOff;
hk = highOff;
ik = outOff;
//Handle tail boundary effect. Use symmetric extension
if(outLen>1) {
outSig[ik] = lowSig[lk]/KL - 2*DELTA*highSig[hk]/KH;
}
else {
outSig[ik] = lowSig[lk];
}
lk += lowStep;
hk += highStep;
ik += iStep;
//Apply lifting step to each "inner" sample
for(i = 2; i<outLen-1; i+=2, ik+=iStep, lk+=lowStep, hk+=highStep) {
outSig[ik] = lowSig[lk]/KL -
DELTA*(highSig[hk-highStep] + highSig[hk])/KH;
}
//Handle head boundary effect if input signal has odd length
if(outLen%2 == 1) {
if(outLen>2){
outSig[ik] = lowSig[lk]/KL -
2*DELTA*highSig[hk-highStep]/KH;
}
}
// Generate intermediate high frequency subband
//Initialize counters
lk = lowOff;
hk = highOff;
ik = outOff + outStep;
//Apply lifting step to each "inner" sample
for(i = 1; i<outLen-1; i+=2, ik+=iStep, hk+=highStep, lk+=lowStep) {
outSig[ik] = highSig[hk]/KH -
GAMMA*(outSig[ik-outStep] + outSig[ik+outStep]);
}
//Handle head boundary effect if output signal has even length
if(outLen % 2 == 0) {
outSig[ik] = highSig[hk]/KH - 2*GAMMA*outSig[ik-outStep];
}
// Generate even samples (inverse low-pass filter)
//Initialize counters
ik = outOff;
//Handle tail boundary effect
//If access the overlap then perform the lifting step.
if(outLen>1) {
outSig[ik] -= 2*BETA*outSig[ik+outStep];
}
ik += iStep;
//Apply lifting step to each "inner" sample
for(i=2; i<outLen-1; i+=2, ik+=iStep) {
outSig[ik] -= BETA*(outSig[ik-outStep] + outSig[ik+outStep]);
}
//Handle head boundary effect if input signal has odd length
if(outLen%2 == 1 && outLen>2) {
outSig[ik] -= 2*BETA*outSig[ik-outStep];
}
// Generate odd samples (inverse high pass-filter)
//Initialize counters
ik = outOff + outStep;
//Apply first lifting step to each "inner" sample
for(i=1; i<outLen-1; i+=2, ik+=iStep) {
outSig[ik] -= ALPHA*(outSig[ik-outStep] + outSig[ik+outStep]);
}
//Handle head boundary effect if input signal has even length
if(outLen%2 == 0) {
outSig[ik] -= 2*ALPHA*outSig[ik-outStep];
}
}
/**
* An implementation of the synthetize_hpf() method that works on int
* data, for the inverse 9x7 wavelet transform using the lifting
* scheme. See the general description of the synthetize_hpf() method in
* the SynWTFilter class for more details.
*
* <P>The low-pass and high-pass subbands are normalized by respectively
* a factor of 1/KL and a factor of 1/KH
*
* <P>The coefficients of the first lifting step are [-DELTA 1 -DELTA].
*
* <P>The coefficients of the second lifting step are [-GAMMA 1 -GAMMA].
*
* <P>The coefficients of the third lifting step are [-BETA 1 -BETA].
*
* <P>The coefficients of the fourth lifting step are [-ALPHA 1 -ALPHA].
*
* @param lowSig This is the array that contains the low-pass
* input signal.
*
* @param lowOff This is the index in lowSig of the first sample to
* filter.
*
* @param lowLen This is the number of samples in the low-pass input
* signal to filter.
*
* @param lowStep This is the step, or interleave factor, of the low-pass
* input signal samples in the lowSig array.
*
* @param highSig This is the array that contains the high-pass input
* signal.
*
* @param highOff This is the index in highSig of the first sample to
* filter.
*
* @param highLen This is the number of samples in the high-pass input
* signal to filter.
*
* @param highStep This is the step, or interleave factor, of the
* high-pass input signal samples in the highSig array.
*
* @param outSig This is the array where the output signal is placed. It
* should be long enough to contain the output signal.
*
* @param outOff This is the index in outSig of the element where to put
* the first output sample.
*
* @param outStep This is the step, or interleave factor, of the output
* samples in the outSig array.
*
* @see SynWTFilter#synthetize_hpf
* */
public
void synthetize_hpf(float[] lowSig, int lowOff, int lowLen, int lowStep,
float[] highSig, int highOff, int highLen, int highStep,
float[] outSig, int outOff, int outStep) {
int i;
int outLen = lowLen + highLen; //Length of the output signal
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