Mercurial > hg > pycsalgos
diff pyCSalgos/ABS/ABSexact.py @ 67:a8d96e67717e
Added the Analysis-By-Synthesis algorithms used in the papers "Analysis-based sparse reconstruction with synthesis-based solvers", "Choosing Analysis or Synthesis Recovery for Sparse Reconstruction" and "A generalization of synthesis and analysis sparsity"
| author | Nic Cleju <nikcleju@gmail.com> |
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| date | Tue, 09 Jul 2013 14:21:10 +0300 |
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--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/pyCSalgos/ABS/ABSexact.py Tue Jul 09 14:21:10 2013 +0300 @@ -0,0 +1,122 @@ +# -*- coding: utf-8 -*- +""" +Algorithms for exact analysis recovery based on synthesis solvers (a.k.a. Analysis by Synthesis, ABS). +Exact reconstruction. + +Author: Nicolae Cleju +""" +__author__ = "Nicolae Cleju" +__license__ = "GPL" +__email__ = "nikcleju@gmail.com" + + +import numpy + +# Import synthesis solvers from pyCSalgos package +import pyCSalgos.BP.l1eq_pd +import pyCSalgos.BP.cvxopt_lp +import pyCSalgos.OMP.omp_QR +import pyCSalgos.SL0.SL0 +import pyCSalgos.TST.RecommendedTST + + +def bp(y,M,Omega,x0, pdtol=1e-3, pdmaxiter=50, cgtol=1e-8, cgmaxiter=200, verbose=False): + """ + ABS-exact: Basis Pursuit (based on l1magic toolbox) + """ + N,n = Omega.shape + D = numpy.linalg.pinv(Omega) + U,S,Vt = numpy.linalg.svd(D) + Aextra = Vt[-(N-n):,:] + + # Create aggregate problem + Atilde = numpy.vstack((numpy.dot(M,D), Aextra)) + ytilde = numpy.concatenate((y,numpy.zeros(N-n))) + + return numpy.dot(D , pyCSalgos.BP.l1eq_pd.l1eq_pd(x0,Atilde,Atilde.T,ytilde, pdtol, pdmaxiter, cgtol, cgmaxiter, verbose)) + +def bp_cvxopt(y,M,Omega): + """ + ABS-exact: Basis Pursuit (based cvxopt) + """ + N,n = Omega.shape + D = numpy.linalg.pinv(Omega) + U,S,Vt = numpy.linalg.svd(D) + Aextra = Vt[-(N-n):,:] + + # Create aggregate problem + Atilde = numpy.vstack((numpy.dot(M,D), Aextra)) + ytilde = numpy.concatenate((y,numpy.zeros(N-n))) + + return numpy.dot(D , pyCSalgos.BP.cvxopt_lp.cvxopt_lp(ytilde, Atilde)) + + +def ompeps(y,M,Omega,epsilon): + """ + ABS-exact: OMP with stopping criterion residual < epsilon + """ + + N,n = Omega.shape + D = numpy.linalg.pinv(Omega) + U,S,Vt = numpy.linalg.svd(D) + Aextra = Vt[-(N-n):,:] + + # Create aggregate problem + Atilde = numpy.vstack((numpy.dot(M,D), Aextra)) + ytilde = numpy.concatenate((y,numpy.zeros(N-n))) + + opts = dict() + opts['stopCrit'] = 'mse' + opts['stopTol'] = epsilon + return numpy.dot(D , pyCSalgos.OMP.omp_QR.greed_omp_qr(ytilde,Atilde,Atilde.shape[1],opts)[0]) + +def ompk(y,M,Omega,k): + """ + ABS-exact: OMP with stopping criterion fixed number of atoms = k + """ + + N,n = Omega.shape + D = numpy.linalg.pinv(Omega) + U,S,Vt = numpy.linalg.svd(D) + Aextra = Vt[-(N-n):,:] + + # Create aggregate problem + Atilde = numpy.vstack((numpy.dot(M,D), Aextra)) + ytilde = numpy.concatenate((y,numpy.zeros(N-n))) + + opts = dict() + opts['stopTol'] = k + return numpy.dot(D , pyCSalgos.OMP.omp_QR.greed_omp_qr(ytilde,Atilde,Atilde.shape[1],opts)[0]) + +def sl0(y,M,Omega, sigma_min, sigma_decrease_factor=0.5, mu_0=2, L=3, true_s=None): + """ + ABS-exact: Smooth L0 (SL0) + """ + + N,n = Omega.shape + D = numpy.linalg.pinv(Omega) + U,S,Vt = numpy.linalg.svd(D) + Aextra = Vt[-(N-n):,:] + + # Create aggregate problem + Atilde = numpy.vstack((numpy.dot(M,D), Aextra)) + ytilde = numpy.concatenate((y,numpy.zeros(N-n))) + + return numpy.dot(D, pyCSalgos.SL0.SL0.SL0(Atilde,ytilde,sigma_min,sigma_decrease_factor,mu_0,L,true_s)) + +def tst_recom(y,M,Omega, nsweep=300, tol=0.00001, xinitial=None, ro=None): + """ + ABS-exact: Two Stage Thresholding (TST) with optimized parameters (see Maleki & Donoho) + """ + + N,n = Omega.shape + D = numpy.linalg.pinv(Omega) + U,S,Vt = numpy.linalg.svd(D) + Aextra = Vt[-(N-n):,:] + + # Create aggregate problem + Atilde = numpy.vstack((numpy.dot(M,D), Aextra)) + ytilde = numpy.concatenate((y,numpy.zeros(N-n))) + + return numpy.dot(D, pyCSalgos.TST.RecommendedTST.RecommendedTST(Atilde, ytilde, nsweep, tol, xinitial, ro)) + \ No newline at end of file