| Wavelet Toolbox | |
Inverse 1-D lifting wavelet transform
Syntax
X = ilwt(AD_In_Place,W) X = ilwt(CA,CD,W) X = ilwt(AD_In_Place,W,LEVEL) X = ilwt(CA,CD,W,LEVEL) X = ilwt(AD_In_Place,W,LEVEL,'typeDEC',typeDEC) X = ilwt(CA,CD,W,LEVEL,'typeDEC',typeDEC)
Description
ilwt performs a 1-D lifting wavelet reconstruction with respect to a particular lifted wavelet that you specify.
X = ilwt(AD_In_Place,W) computes the reconstructed vector X using the approximation and detail coefficients vector AD_In_Place obtained by a lifting wavelet reconstruction. W is a lifted wavelet name (see liftwave).
X = ilwt(CA,CD,W) computes the reconstructed vector X using the approximation coefficients vector CA and detail coefficients vector CD obtained by a lifting wavelet reconstruction.
X = ilwt(AD_In_Place,W,LEVEL) or X = ILWT(CA,CD,W,LEVEL) computes the lifting wavelet reconstruction, at level LEVEL.
X = ilwt(AD_In_Place,W,LEVEL,'typeDEC',typeDEC) or X = ilwt(CA,CD,W,LEVEL,'typeDEC',typeDEC) with typeDEC = 'w' or 'wp' computes the wavelet or the wavelet packet decomposition using lifting, at level LEVEL.
Instead of a lifted wavelet name, you may use the associated lifting scheme LS: X = ilwt(...,LS,...) instead of X = ILWT(...,W,...).
For more information about lifting schemes, see lsinfo.
Examples
% Start from the Haar wavelet and get the % corresponding lifting scheme. lshaar = liftwave('haar'); % Add a primal ELS to the lifting scheme. els = {'p',[-0.125 0.125],0}; lsnew = addlift(lshaar,els); % Perform LWT at level 1 of a simple signal. x = 1:8; [cA,cD] = lwt(x,lsnew); % Perform integer LWT of the same signal. lshaarInt = liftwave('haar','int2int'); lsnewInt = addlift(lshaarInt,els); [cAint,cDint] = lwt(x,lsnewInt); % Invert the two transforms. xRec = ilwt(cA,cD,lsnew); err = max(max(abs(x-xRec))) err = 4.4409e-016 xRecInt = ilwt(cAint,cDint,lsnewInt); errInt = max(max(abs(x-xRecInt))) errInt = 0
See Also
lwt
| | idwt2 | ilwt2 | |
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