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BSBL_BO.m
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BSBL_BO.m
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function Result = BSBL_BO(Phi, y, blkStartLoc, LearnLambda, varargin)
% BSBL-BO: Recover block sparse signal (1D) exploiting intra-block correlation, given the block partition.
%
% The algorithm solves the inverse problem for the block sparse
% model with known block partition:
% y = Phi * x + v
%
%
% ============================== INPUTS ==============================
% Phi : N X M known matrix
%
% y : N X 1 measurement vector
%
% blkStartLoc : Start location of each block
%
% LearnLambda : (1) If LearnLambda = 1, use the lambda learning rule for very LOW SNR cases (SNR<10dB)
% (using lambda=std(y)*1e-2 or user-input value as initial value)
% (2) If LearnLambda = 2, use the lambda learning rule for medium noisy cases (SNR>10dB)
% (using lambda=std(y)*1e-2 or user-input value as initial value)
% (3) If LearnLambda = 0, do not use the lambda learning rule
% ((using lambda=1e-14 or user-input value as initial value)
%
%
% [varargin values -- in most cases you can use the default values]
%
% 'LEARNTYPE' : LEARNTYPE = 0: Ignore intra-block correlation
% LEARNTYPE = 1: Exploit intra-block correlation
% [ Default: LEARNTYPE = 1 ]
%
% 'PRUNE_GAMMA' : threshold to prune out small gamma_i
% (generally, 10^{-3} or 10^{-2})
%
% 'LAMBDA' : user-input value for lambda
% [ Default: LAMBDA=1e-14 when LearnLambda=0; LAMBDA=std(y)*1e-2 in noisy cases]
%
% 'MAX_ITERS' : Maximum number of iterations.
% [ Default value: MAX_ITERS = 600 ]
%
% 'EPSILON' : Solution accurancy tolerance parameter
% [ Default value: EPSILON = 1e-8 ]
%
% 'PRINT' : Display flag. If = 1: show output; If = 0: supress output
% [ Default value: PRINT = 0 ]
%
% ============================== OUTPUTS ==============================
% Result :
% Result.x : the estimated block sparse signal
% Result.gamma_used : indexes of nonzero groups in the sparse signal
% Result.gamma_est : the gamma values of all the groups of the signal
% Result.B : the final value of the B
% Result.count : iteration times
% Result.lambda : the final value of lambda
%
%
% ========================= Command examples =============================
% < Often-used command >
% For most noisy environment (SNR > 10dB):
%
% Result = BSBL_BO(Phi, y, blkStartLoc, 2);
%
% For very low SNR cases (SNR < 10 dB):
%
% Result = BSBL_BO(Phi, y, blkStartLoc, 1);
%
% For noiseless cases:
%
% Result = BSBL_BO(Phi, y, blkStartLoc, 0);
%
% To recover non-Sparse structured signals (noiseless):
% Result = BSBL_BO(Phi,y,groupStartLoc,0,'prune_gamma',-1);
% ('prune_gamma' can be set any non positive constant)
%
% < Full-Command Example >
% Result = BSBL_BO(Phi, y, blkStartLoc, learnlambda, ...
% 'LEARNTYPE', 1,...
% 'PRUNE_GAMMA',1e-2,...
% 'LAMBDA',1e-3,...
% 'MAX_ITERS', 800,...
% 'EPSILON', 1e-8,...
% 'PRINT',0);
%
% ================================= See Also =============================
% EBSBL_BO, BSBL_EM, BSBL_L1, EBSBL_L1, TMSBL, TSBL
%
% ================================ Reference =============================
% [1] Zhilin Zhang, Bhaskar D. Rao, Extension of SBL Algorithms for the
% Recovery of Block Sparse Signals with Intra-Block Correlation,
% available at: http://arxiv.org/abs/1201.0862
%
% [2] Zhilin Zhang, Tzyy-Ping Jung, Scott Makeig, Bhaskar D. Rao,
% Low Energy Wireless Body-Area Networks for Fetal ECG Telemonitoring
% via the Framework of Block Sparse Bayesian Learning,
% available at: http://arxiv.org/pdf/1205.1287v1.pdf
%
% [3] webpage: http://dsp.ucsd.edu/~zhilin/BSBL.html, or
% https://sites.google.com/site/researchbyzhang/bsbl
%
% ============= Author =============
% Zhilin Zhang (z4zhang@ucsd.edu, zhangzlacademy@gmail.com)
%
% ============= Version =============
% 1.4 (07/23/2012) debug
% 1.3 (05/30/2012) make faster
% 1.2 (05/28/2012)
% 1.1 (01/22/2012)
% 1.0 (08/27/2011)
%
% scaling...
scl = std(y);
if (scl < 0.4) | (scl > 1)
y = y/scl*0.4;
end
% Default Parameter Values for Any Cases
EPSILON = 1e-8; % solution accurancy tolerance
MAX_ITERS = 600; % maximum iterations
PRINT = 0; % don't show progress information
LEARNTYPE = 1; % adaptively estimate the covariance matrix B
if LearnLambda == 0
lambda = 1e-12;
PRUNE_GAMMA = 1e-3;
elseif LearnLambda == 2
lambda = scl * 1e-2;
PRUNE_GAMMA = 1e-2;
elseif LearnLambda == 1
lambda = scl * 1e-2;
PRUNE_GAMMA = 1e-2;
else
error(['Unrecognized Value for Input Argument ''LearnLambda''']);
end
if(mod(length(varargin),2)==1)
error('Optional parameters should always go by pairs\n');
else
for i=1:2:(length(varargin)-1)
switch lower(varargin{i})
case 'learntype'
LEARNTYPE = varargin{i+1};
if LEARNTYPE ~= 1 & LEARNTYPE ~= 0
error(['Unrecognized Value for Input Argument ''LEARNTYPE''']);
end
case 'prune_gamma'
PRUNE_GAMMA = varargin{i+1};
case 'lambda'
lambda = varargin{i+1};
case 'epsilon'
EPSILON = varargin{i+1};
case 'print'
PRINT = varargin{i+1};
case 'max_iters'
MAX_ITERS = varargin{i+1};
otherwise
error(['Unrecognized parameter: ''' varargin{i} '''']);
end
end
end
if PRINT
fprintf('\n====================================================\n');
fprintf(' Running BSBL-BO ....... \n');
fprintf(' Information about parameters...\n');
fprintf('====================================================\n');
fprintf('PRUNE_GAMMA : %e\n',PRUNE_GAMMA);
fprintf('lambda : %e\n',lambda);
fprintf('LearnLambda : %d\n',LearnLambda);
fprintf('LearnType : %d\n',LEARNTYPE);
fprintf('EPSILON : %e\n',EPSILON);
fprintf('MAX_ITERS : %d\n\n',MAX_ITERS);
end
%% Initialization
[N,M] = size(Phi);
Phi0 = Phi;
blkStartLoc0 = blkStartLoc;
p = length(blkStartLoc); % block number
for k = 1 : p-1
blkLenList(k) = blkStartLoc(k+1)-blkStartLoc(k);
end
blkLenList(p) = M - blkStartLoc(end)+1;
maxLen = max(blkLenList);
if sum(blkLenList == maxLen) == p,
equalSize = 1;
else
equalSize = 0;
end
for k = 1 : p
Sigma0{k} = eye(blkLenList(k));
end
gamma = ones(p,1);
keep_list = [1:p]';
usedNum = length(keep_list);
mu_x = zeros(M,1);
count = 0;
%% Iteration
while (1)
count = count + 1;
%=========== Prune weighys as yheir hyperparameyers go yo zero ==============
if (min(gamma) < PRUNE_GAMMA)
index = find(gamma > PRUNE_GAMMA);
usedNum = length(index);
keep_list = keep_list(index);
if isempty(keep_list),
fprintf('\n====================================================================================\n');
fprintf('x becomes zero vector. The solution may be incorrect. \n');
fprintf('Current ''prune_gamma'' = %g, and Current ''EPSILON'' = %g.\n',PRUNE_GAMMA,EPSILON);
fprintf('Try smaller values of ''prune_gamma'' and ''EPSILON'' or normalize ''y'' to unit norm.\n');
fprintf('====================================================================================\n\n');
break;
end;
blkStartLoc = blkStartLoc(index);
blkLenList = blkLenList(index);
% prune gamma and associated components in Sigma0
gamma = gamma(index);
temp = Sigma0;
Sigma0 = [];
for k = 1 : usedNum
Sigma0{k} = temp{index(k)};
end
% construct new Phi
temp = [];
for k = 1 : usedNum
temp = [temp, Phi0(:,blkStartLoc(k):blkStartLoc(k)+blkLenList(k)-1)];
end
Phi = temp;
%clear temp;
end
%=================== Compute new weights =================
mu_old = mu_x;
PhiBPhi = zeros(N);
currentLoc = 0;
for i = 1 : usedNum
currentLen = size(Sigma0{i},1);
currentLoc = currentLoc + 1;
currentSeg = currentLoc : 1 : currentLoc + currentLen - 1;
PhiBPhi = PhiBPhi + Phi(:, currentSeg)*Sigma0{i}*Phi(:, currentSeg)';
currentLoc = currentSeg(end);
end
H = Phi' /(PhiBPhi + lambda * eye(N));
Hy = H * y;
HPhi = H * Phi;
mu_x = zeros(size(Phi,2),1);
Sigma_x = [];
Cov_x = [];
B = []; invB = []; B0 = zeros(maxLen); r0 = zeros(1); r1 = zeros(1);
currentLoc = 0;
for i = 1 : usedNum
currentLen = size(Sigma0{i},1);
currentLoc = currentLoc + 1;
seg = currentLoc : 1 : currentLoc + currentLen - 1;
mu_x(seg) = Sigma0{i} * Hy(seg); % solution
Sigma_x{i} = Sigma0{i} - Sigma0{i} * HPhi(seg,seg) * Sigma0{i};
Cov_x{i} = Sigma_x{i} + mu_x(seg) * mu_x(seg)';
currentLoc = seg(end);
%=========== Learn correlation structure in blocks ===========
% do not consider correlation structure in each block
if LEARNTYPE == 0
B{i} = eye(currentLen);
invB{i} = eye(currentLen);
% constrain all the blocks have the same correlation structure
elseif LEARNTYPE == 1
if equalSize == 0
if currentLen > 1
temp = Cov_x{i}/gamma(i);
r0 = r0 + mean(diag(temp));
r1 = r1 + mean(diag(temp,1));
end
elseif equalSize == 1
B0 = B0 + Cov_x{i}/gamma(i);
end
end % end of learnType
end
%=========== Learn correlation structure in blocks with Constraint 1 ===========
% If blocks have the same size
if (equalSize == 1) & (LEARNTYPE == 1)
% Constrain all the blocks have the same correlation structure
% (an effective strategy to avoid overfitting)
b = (mean(diag(B0,1))/mean(diag(B0)));
if abs(b) >= 0.99, b = 0.99*sign(b); end;
bs = [];
for j = 1 : maxLen, bs(j) = (b)^(j-1); end;
B0 = toeplitz(bs);
for i = 1 : usedNum
B{i} = B0;
invB{i} = inv(B{i});
end
% if blocks have different sizes
elseif (equalSize == 0) & (LEARNTYPE == 1)
r = r1/r0; if abs(r) >= 0.99, r = 0.99*sign(r); end;
for i = 1 : usedNum
currentLen = size(Cov_x{i},1);
bs = [];
for j = 1 : currentLen, bs(j) = r^(j-1); end;
B{i} = toeplitz(bs);
invB{i} = inv(B{i});
end
end
% estimate gamma(i) and lambda
if LearnLambda == 1
gamma_old = gamma;
lambdaComp = 0; currentLoc = 0;
for i = 1 : usedNum
currentLen = size(Sigma_x{i},1);
currentLoc = currentLoc + 1;
currentSeg = currentLoc : 1 : currentLoc + currentLen - 1;
gamma(i) = gamma_old(i)*norm( sqrtm(B{i})*Hy(currentSeg) )/sqrt(trace(HPhi(currentSeg,currentSeg)*B{i}));
lambdaComp = lambdaComp + trace(Phi(:,currentSeg)*Sigma_x{i}*Phi(:,currentSeg)');
Sigma0{i} = B{i} * gamma(i);
currentLoc = currentSeg(end);
end
lambda = norm(y - Phi * mu_x,2)^2/N + lambdaComp/N;
elseif LearnLambda == 2
gamma_old = gamma;
lambdaComp = 0; currentLoc = 0;
for i = 1 : usedNum
currentLen = size(Sigma_x{i},1);
currentLoc = currentLoc + 1;
currentSeg = currentLoc : 1 : currentLoc + currentLen - 1;
gamma(i) = gamma_old(i)*norm( sqrtm(B{i})*Hy(currentSeg) )/sqrt(trace(HPhi(currentSeg,currentSeg)*B{i}));
lambdaComp = lambdaComp + trace(Sigma_x{i}*invB{i})/gamma_old(i);
Sigma0{i} = B{i} * gamma(i);
currentLoc = currentSeg(end);
end
lambda = norm(y - Phi * mu_x,2)^2/N + lambda * (length(mu_x) - lambdaComp)/N;
else % only estimate gamma(i)
gamma_old = gamma;
currentLoc = 0;
for i = 1 : usedNum
% gamma(i) = trace(invB{i} * Cov_x{i})/size(Cov_x{i},1);
currentLen = size(Sigma0{i},1);
currentLoc = currentLoc + 1;
seg = currentLoc : 1 : currentLoc + currentLen - 1;
gamma(i) = gamma_old(i)*norm( sqrtm(B{i})*Hy(seg) )/sqrt(trace(HPhi(seg,seg)*B{i}));
Sigma0{i} = B{i} * gamma(i);
currentLoc = seg(end);
end
end
% ================= Check stopping conditions, eyc. ==============
if (size(mu_x) == size(mu_old))
dmu = max(max(abs(mu_old - mu_x)));
if (dmu < EPSILON) break; end;
end;
if (PRINT)
disp([' iters: ',num2str(count),...
' num coeffs: ',num2str(usedNum), ...
' min gamma: ', num2str(min(gamma)),...
' gamma change: ',num2str(max(abs(gamma - gamma_old))),...
' mu change: ', num2str(dmu)]);
end;
if (count >= MAX_ITERS), if PRINT, fprintf('Reach max iterations. Stop\n\n'); end; break; end;
end;
if isempty(keep_list)
Result.x = zeros(M,1);
Result.gamma_used = [];
Result.gamma_est = zeros(p,1);
Result.B = B;
Result.count = count;
Result.lambdatrace = lambda;
else
%% Expand hyperparameyers
gamma_used = sort(keep_list);
gamma_est = zeros(p,1);
gamma_est(keep_list,1) = gamma;
%% reconstruct the original signal
x = zeros(M,1);
currentLoc = 0;
for i = 1 : usedNum
currentLen = size(Sigma0{i},1);
currentLoc = currentLoc + 1;
seg = currentLoc : 1 : currentLoc + currentLen - 1;
realLocs = blkStartLoc0(keep_list(i)) : blkStartLoc0(keep_list(i))+currentLen-1;
x( realLocs ) = mu_x( seg );
currentLoc = seg(end);
end
if (scl < 0.4) | (scl > 1)
Result.x = x * scl/0.4;
else
Result.x = x;
end
Result.gamma_used = gamma_used;
Result.gamma_est = gamma_est;
Result.B = B;
Result.count = count;
Result.lambda = lambda;
end
return;