📄 meiwa2.m
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function x = meiwa2(c,pat,tp)% meiwa2 - 2D inverse mirror-extended wave atom transform% -----------------% INPUT% --% c is a cell array which contains the wave atom coefficients. If% tp=='ortho', then c{j}{m1,m2}(n1,n2) is the coefficient at scale j,% frequency index (m1,m2) and spatial index (n1,n2). If% tp=='directional', then c{j,d}{m1,m2}(n1,n2) with d=1,2 are the% coefficients at scale j, frequency index (m1,m2) and spatial index% (n1,n2). If tp=='complex', then c{j}{m1,m2)(n1,n2) is the% complex-valued coefficients at scale j, frequency index (m1,m2) and% spatial index (n1,n2). Notice thatm, for the mirror-extended wave% atoms, the spatial indices wrap around once.% --% pat specifies the type of frequency partition which satsifies% parabolic scaling relationship. pat can either be 'p' or 'q'.% --% tp is the type of tranform.% 'ortho': frame based on the orthobasis construction of % the standard wave atom% 'directional': real-valued frame with single oscillation direction% 'complex': complex-valued frame% -----------------% OUTPUT% --% x is a real N-by-N matrix. N is a power of 2.% -----------------% Written by Lexing Ying and Laurent Demanet, 2007 if( ismember(tp, {'ortho','directional','complex'})==0 | ismember(pat, {'p','q','u'})==0 ) error('wrong'); end if(strcmp(tp, 'ortho')==1) %--------------------------------------------------------- T = 0; for s=1:length(c) nw = length(c{s}); for I=1:nw for J=1:nw T = T + prod(size(c{s}{I,J})); end end end N = sqrt(T/4); %redundancy of 4 lst = freq_pat(N,pat); E = 2^length(lst); A = 2*(N+E); %extension f = zeros(A,A); %------------------ for s=1:length(lst) nw = length(lst{s}); for I=0:nw-1 for J=0:nw-1 if(~isempty(c{s}{I+1,J+1})) B = 2^(s-1); D = 2*B; Ict = I*B; Jct = J*B; %starting position in freq if(mod(I,2)==0) Ifm = Ict-2/3*B; Ito = Ict+4/3*B; else Ifm = Ict-1/3*B; Ito = Ict+5/3*B; end if(mod(J,2)==0) Jfm = Jct-2/3*B; Jto = Jct+4/3*B; else Jfm = Jct-1/3*B; Jto = Jct+5/3*B; end res = fft2(c{s}{I+1,J+1}) / sqrt(prod(size(c{s}{I+1,J+1}))) / 2; %LEXING: IMPORTANT for id=0:1 if(id==0) Idx = [ceil(Ifm):floor(Ito)]; Icf = kf_rt(Idx/B*pi, I); else Idx = [ceil(-Ito):floor(-Ifm)]; Icf = kf_lf(Idx/B*pi, I); end for jd=0:1 if(jd==0) Jdx = [ceil(Jfm):floor(Jto)]; Jcf = kf_rt(Jdx/B*pi, J); else Jdx = [ceil(-Jto):floor(-Jfm)]; Jcf = kf_lf(Jdx/B*pi, J); end f(mod(Idx,A)+1,mod(Jdx,A)+1) = f(mod(Idx,A)+1,mod(Jdx,A)+1) + ( Icf.'*Jcf ) .* res(mod(Idx,D)+1,mod(Jdx,D)+1); end end end end end end f = mecombine(f',E)'; f = mecombine(f,E); x = idct2(f); elseif(strcmp(tp,'complex')==1) %--------------------------------------------------------- T = 0; for s=1:length(c) nw = length(c{s}); for I=1:nw for J=1:nw T = T + prod(size(c{s}{I,J})); end end end N = sqrt(T/4); %redundancy of 4 lst = freq_pat(N,pat); E = 2^length(lst); A = 2*(N+E); %extension f = zeros(A,A); %------------------ for s=1:length(lst) nw = length(lst{s}); for I=0:nw-1 for J=0:nw-1 if(~isempty(c{s}{I+1,J+1})) B = 2^(s-1); D = 2*B; Ict = I*B; Jct = J*B; %starting position in freq if(mod(I,2)==0) Ifm = Ict-2/3*B; Ito = Ict+4/3*B; else Ifm = Ict-1/3*B; Ito = Ict+5/3*B; end if(mod(J,2)==0) Jfm = Jct-2/3*B; Jto = Jct+4/3*B; else Jfm = Jct-1/3*B; Jto = Jct+5/3*B; end res = fft2(c{s}{I+1,J+1}) / sqrt(prod(size(c{s}{I+1,J+1}))); %res = zeros(D,D); Idx = [ceil(Ifm):floor(Ito)]; Icf = kf_rt(Idx/B*pi, I); Jdx = [ceil(Jfm):floor(Jto)]; Jcf = kf_rt(Jdx/B*pi, J); f(mod(Idx,A)+1,mod(Jdx,A)+1) = f(mod(Idx,A)+1,mod(Jdx,A)+1) + abs( Icf.'*Jcf ) .* res(mod(Idx,D)+1,mod(Jdx,D)+1); end end end end f = mecombine(f',E)'; f = mecombine(f,E); x = idct2(f); elseif(strcmp(tp,'directional')==1) %--------------------------------------------------------- c1 = c(:,1); c2 = c(:,2); T = 0; for s=1:length(c1) nw = length(c1{s}); for I=1:nw for J=1:nw T = T + prod(size(c1{s}{I,J})) + prod(size(c2{s}{I,J})); end end end N = sqrt(T/4); lst = freq_pat(N,pat); E = 2^length(lst); A = 2*(N+E); %extension f = zeros(A,A); %------------------ for s=1:length(lst) nw = length(lst{s}); for I=0:nw-1 for J=0:nw-1 if(~isempty(c1{s}{I+1,J+1})) B = 2^(s-1); D = 2*B; Ict = I*B; Jct = J*B; %starting position in freq if(mod(I,2)==0) Ifm = Ict-2/3*B; Ito = Ict+4/3*B; else Ifm = Ict-1/3*B; Ito = Ict+5/3*B; end if(mod(J,2)==0) Jfm = Jct-2/3*B; Jto = Jct+4/3*B; else Jfm = Jct-1/3*B; Jto = Jct+5/3*B; end [a,b] = size(c1{s}{I+1,J+1}); tmp = zeros(a,2*b); tmp(:,1:end/2) = c1{s}{I+1,J+1}/sqrt(2); res = fft2(tmp) / sqrt(prod(size(tmp))); Idx = [ceil(Ifm):floor(Ito)]; Icf = kf_rt(Idx/B*pi, I); Jdx = [ceil(Jfm):floor(Jto)]; Jcf = kf_rt(Jdx/B*pi, J); f(mod(Idx,A)+1,mod(Jdx,A)+1) = f(mod(Idx,A)+1,mod(Jdx,A)+1) + ( Icf.'*Jcf ) .* res(mod(Idx,D)+1,mod(Jdx,D)+1); Idx = [ceil(-Ito):floor(-Ifm)]; Icf = kf_lf(Idx/B*pi, I); Jdx = [ceil(-Jto):floor(-Jfm)]; Jcf = kf_lf(Jdx/B*pi, J); f(mod(Idx,A)+1,mod(Jdx,A)+1) = f(mod(Idx,A)+1,mod(Jdx,A)+1) + ( Icf.'*Jcf ) .* res(mod(Idx,D)+1,mod(Jdx,D)+1); [a,b] = size(c2{s}{I+1,J+1}); tmp = zeros(a,2*b); tmp(:,1:end/2) = c2{s}{I+1,J+1}/sqrt(2); res = fft2(tmp) / sqrt(prod(size(tmp))); Idx = [ceil(Ifm):floor(Ito)]; Icf = kf_rt(Idx/B*pi, I); Jdx = [ceil(-Jto):floor(-Jfm)]; Jcf = kf_lf(Jdx/B*pi, J); f(mod(Idx,A)+1,mod(Jdx,A)+1) = f(mod(Idx,A)+1,mod(Jdx,A)+1) + ( Icf.'*Jcf ) .* res(mod(Idx,D)+1,mod(Jdx,D)+1); Idx = [ceil(-Ito):floor(-Ifm)]; Icf = kf_lf(Idx/B*pi, I); Jdx = [ceil(Jfm):floor(Jto)]; Jcf = kf_rt(Jdx/B*pi, J); f(mod(Idx,A)+1,mod(Jdx,A)+1) = f(mod(Idx,A)+1,mod(Jdx,A)+1) + ( Icf.'*Jcf ) .* res(mod(Idx,D)+1,mod(Jdx,D)+1); end end end end f = mecombine(f',E)'; f = mecombine(f,E); x = idct2(f); else %--------------------------------------------------------- error('wrong'); end⌨️ 快捷键说明
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