/**
* DaubJ wavelets have the following properties:<br>
*
* <ul>
* <li>Conserve the signal's energy
* <li>If the signal is approximately polynomial of degree J/2-1 or less within the support then
* fluctuations are approximately zero.
* <li>The sum of the scaling numbers is sqrt(2)
* <li>The sum of the wavelet numbers is 0
* </ul>
*
* @param J The wavelet's degree.
* @return Description of the DaubJ wavelet.
*/
public static WaveletDescription<WlCoef_F32> daubJ_F32(int J) {
if (J != 4) {
throw new IllegalArgumentException("Only 4 is currently supported");
}
WlCoef_F32 coef = new WlCoef_F32();
coef.offsetScaling = 0;
coef.offsetWavelet = 0;
coef.scaling = new float[4];
coef.wavelet = new float[4];
double sqrt3 = Math.sqrt(3);
double div = 4.0 * Math.sqrt(2);
coef.scaling[0] = (float) ((1 + sqrt3) / div);
coef.scaling[1] = (float) ((3 + sqrt3) / div);
coef.scaling[2] = (float) ((3 - sqrt3) / div);
coef.scaling[3] = (float) ((1 - sqrt3) / div);
coef.wavelet[0] = coef.scaling[3];
coef.wavelet[1] = -coef.scaling[2];
coef.wavelet[2] = coef.scaling[1];
coef.wavelet[3] = -coef.scaling[0];
WlBorderCoefStandard<WlCoef_F32> inverse = new WlBorderCoefStandard<>(coef);
return new WaveletDescription<>(new BorderIndex1D_Wrap(), coef, inverse);
}
/**
* Computes inverse coefficients
*
* @param border
* @param forward Forward coefficients.
* @param inverse Inverse used in the inner portion of the data stream.
* @return
*/
private static WlBorderCoef<WlCoef_F32> computeBorderCoefficients(
BorderIndex1D border, WlCoef_F32 forward, WlCoef_F32 inverse) {
int N = Math.max(forward.getScalingLength(), forward.getWaveletLength());
N += N % 2;
N *= 2;
border.setLength(N);
// Because the wavelet transform is a linear invertible system the inverse coefficients
// can be found by creating a matrix and inverting the matrix. Boundary conditions are then
// extracted from this inverted matrix.
DenseMatrix64F A = new DenseMatrix64F(N, N);
for (int i = 0; i < N; i += 2) {
for (int j = 0; j < forward.scaling.length; j++) {
int index = border.getIndex(j + i + forward.offsetScaling);
A.add(i, index, forward.scaling[j]);
}
for (int j = 0; j < forward.wavelet.length; j++) {
int index = border.getIndex(j + i + forward.offsetWavelet);
A.add(i + 1, index, forward.wavelet[j]);
}
}
LinearSolver<DenseMatrix64F> solver = LinearSolverFactory.linear(N);
if (!solver.setA(A) || solver.quality() < 1e-5) {
throw new IllegalArgumentException("Can't invert matrix");
}
DenseMatrix64F A_inv = new DenseMatrix64F(N, N);
solver.invert(A_inv);
int numBorder = UtilWavelet.borderForwardLower(inverse) / 2;
WlBorderCoefFixed<WlCoef_F32> ret = new WlBorderCoefFixed<>(numBorder, numBorder + 1);
ret.setInnerCoef(inverse);
// add the lower coefficients first
for (int i = 0; i < ret.getLowerLength(); i++) {
computeLowerCoef(inverse, A_inv, ret, i * 2);
}
// add upper coefficients
for (int i = 0; i < ret.getUpperLength(); i++) {
computeUpperCoef(inverse, N, A_inv, ret, i * 2);
}
return ret;
}
private static WlCoef_F32 computeInnerInverseBiorthogonal(WlCoef_F32 coef) {
WlCoef_F32 ret = new WlCoef_F32();
// center at zero
ret.offsetScaling = -coef.wavelet.length / 2;
// center at one
ret.offsetWavelet = 1 - coef.scaling.length / 2;
ret.scaling = new float[coef.wavelet.length];
ret.wavelet = new float[coef.scaling.length];
for (int i = 0; i < ret.scaling.length; i++) {
if (i % 2 == 0) ret.scaling[i] = -coef.wavelet[i];
else ret.scaling[i] = coef.wavelet[i];
}
for (int i = 0; i < ret.wavelet.length; i++) {
if (i % 2 == 1) ret.wavelet[i] = -coef.scaling[i];
else ret.wavelet[i] = coef.scaling[i];
}
return ret;
}
/**
* Daub J/K biorthogonal wavelets have the following properties:<br>
*
* <ul>
* <li>DO NOT conserve the signal's energy
* <li>If the signal is approximately polynomial of degree (J-1)/2-1 within the support then
* fluctuations are approximately zero.
* <li>The sum of the scaling numbers is 1
* <li>The sum of the wavelet numbers is 0
* </ul>
*
* @param J The wavelet's degree. K = J-2.
* @param borderType How image borders are handled.
* @return Description of the Daub J/K wavelet.
*/
public static WaveletDescription<WlCoef_F32> biorthogonal_F32(int J, BorderType borderType) {
if (J != 5) {
throw new IllegalArgumentException("Only 5 is currently supported");
}
WlCoef_F32 forward = new WlCoef_F32();
forward.offsetScaling = -2;
forward.offsetWavelet = 0;
forward.scaling = new float[5];
forward.wavelet = new float[3];
forward.scaling[0] = (float) (-1.0 / 8.0);
forward.scaling[1] = (float) (2.0 / 8.0);
forward.scaling[2] = (float) (6.0 / 8.0);
forward.scaling[3] = (float) (2.0 / 8.0);
forward.scaling[4] = (float) (-1.0 / 8.0);
forward.wavelet[0] = -1.0f / 2.0f;
forward.wavelet[1] = 1;
forward.wavelet[2] = -1.0f / 2.0f;
BorderIndex1D border;
WlBorderCoef<WlCoef_F32> inverse;
if (borderType == BorderType.REFLECT) {
WlCoef_F32 inner = computeInnerInverseBiorthogonal(forward);
border = new BorderIndex1D_Reflect();
inverse = computeBorderCoefficients(border, forward, inner);
} else if (borderType == BorderType.WRAP) {
WlCoef_F32 inner = computeInnerInverseBiorthogonal(forward);
inverse = new WlBorderCoefStandard<>(inner);
border = new BorderIndex1D_Wrap();
} else {
throw new IllegalArgumentException("Unsupported border type: " + borderType);
}
return new WaveletDescription<>(border, forward, inverse);
}
