Publications

Topics:
  1. A. M. Bronstein, M. M. Bronstein, E. Gordon, R. Kimmel, Fusion of 2D and 3D data in three-dimensional face recognition, Proc. Int'l Conf. on Image Processing (ICIP), 2004 details

    Fusion of 2D and 3D data in three-dimensional face recognition

    A. M. Bronstein, M. M. Bronstein, E. Gordon, R. Kimmel
    Proc. Int'l Conf. on Image Processing (ICIP), 2004

    We discuss the synthesis between the 3D and the 2D data in three-dimensional face recognition. We show how to compensate for the illumination and facial expressions using the 3D facial geometry and present the approach of canonical images, which allows to incorporate geometric information into standard face recognition approaches.

    M. M. Bronstein, A. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi,, Optimal sparse representations for blind source separation and blind deconvolution: a learning approach, Proc. Int'l Conf. on Image Processing (ICIP), 2004 details

    Optimal sparse representations for blind source separation and blind deconvolution: a learning approach

    M. M. Bronstein, A. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi,
    Proc. Int'l Conf. on Image Processing (ICIP), 2004

    We present a generic approach, which allows to adapt sparse blind deconvolution and blind source separation algorithms to arbitrary sources. The key idea is to bring the problem to the case in which the underlying sources are sparse by applying a sparsifying transformation on the mixtures. We present simulation results and show that such transformation can be found by training. Properties of the optimal sparsifying transformation are highlighted by an example with aerial images.

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi, Fast relative Newton algorithm for blind deconvolution of images, Proc. Int'l Conf. on Image Processing (ICIP), 2004 details

    Fast relative Newton algorithm for blind deconvolution of images

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi
    Proc. Int'l Conf. on Image Processing (ICIP), 2004

    We present an efficient Newton-like algorithm for quasi-maximum likelihood (QML) blind deconvolution of images. This algorithm exploits the sparse structure of the Hessian. An optimal distribution-shaping approach by means of sparsification allows one to use simple and convenient sparsity prior for processing of a wide range of natural images. Simulation results demonstrate the efficiency of the proposed method.

    A. M. Bronstein, M. M. Bronstein, R. Kimmel, A. Spira, Face recognition from facial surface metric, Proc. European Conf. on Computer Vision (ECCV), 2004 details

    Face recognition from facial surface metric

    A. M. Bronstein, M. M. Bronstein, R. Kimmel, A. Spira
    Proc. European Conf. on Computer Vision (ECCV), 2004

    Recently, a 3D face recognition approach based on geometric invariant signatures, has been proposed. The key idea is a representation of the facial surface, invariant to isometric deformations, such as those resulting from facial expressions. One important stage in the construction of the geometric invariants involves in measuring geodesic distances on triangulated surfaces, which is carried out by the fast marching on triangulated domains algorithm. Proposed here is a method that uses only the metric tensor of the surface for geodesic distance computation. That is, the explicit integration of the surface in 3D from its gradients is not needed for the recognition task. It enables the use of simple and cost-efficient 3D acquisition techniques such as photometric stereo. Avoiding the explicit surface reconstruction stage saves computational time and reduces numerical errors.

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Blind source separation using block-coordinate relative Newton method, Signal Processing, Vol. 84(8), 2004 details

    Blind source separation using block-coordinate relative Newton method

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky
    Signal Processing, Vol. 84(8), 2004

    Presented here is a generalization of the relative Newton method, recently proposed for quasi maximum likelihood blind source separation. Special structure of the Hessian matrix allows performing block-coordinate Newton descent, which significantly reduces the algorithm computational complexity and boosts its performance. Simulations based on artificial and real data showed that the separation quality using the proposed algorithm is superior compared to other accepted blind source separation methods.

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Blind source separation using the block-coordinate relative Newton method, Proc. Int'l Conf. on Independent Component Analysis and Blind Signal Separation, Lecture Notes in Comp. Science No. 3195, Springer, 2004 details

    Blind source separation using the block-coordinate relative Newton method

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky
    Proc. Int'l Conf. on Independent Component Analysis and Blind Signal Separation, Lecture Notes in Comp. Science No. 3195, Springer, 2004

    Presented here is a generalization of the modified relative Newton method, recently proposed by Zibulevsky for quasi-maximum likelihood blind source separation. The special structure of the Hessian matrix allows to perform block-coordinate Newton descent, which significantly reduces the algorithm computational complexity and boosts its performance. Simulations based on artificial and real data show that the separation quality using the proposed algorithm outperforms other accepted blind source separation methods.

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi, QML blind deconvolution: asymptotic analysis, Proc. Int'l Conf. on Independent Component Analysis and Blind Signal Separation, 2004 details

    QML blind deconvolution: asymptotic analysis

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi
    Proc. Int'l Conf. on Independent Component Analysis and Blind Signal Separation, 2004

    Blind deconvolution is considered as a problem of quasi-maximum likelihood (QML) estimation of the restoration kernel. Simple closed-form expressions for the asymptotic estimation error are derived. The asymptotic performance bounds coincide with the Cramér-Rao bounds, when the true ML estimator is used. Conditions for asymptotic stability of the QML estimator are derived. Special cases when the estimator is super-efficient are discussed.

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi, Optimal sparse representations for blind deconvolution of images, Proc. Int'l Conf. on Independent Component Analysis and Blind Signal Separation, 2004 details

    Optimal sparse representations for blind deconvolution of images

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi
    Proc. Int'l Conf. on Independent Component Analysis and Blind Signal Separation, 2004

    The relative Newton algorithm, previously proposed for quasi-maximum likelihood blind source separation and blind deconvolution of one-dimensional signals is generalized for blind deconvolution of images. Smooth approximation of the absolute value is used in modeling the log probability density function, which is suitable for sparse sources. We propose a method of sparsification, which allows blind deconvolution of sources with arbitrary distribution, and show how to find optimal sparsifying transformations by training.

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi, Quasi maximum likelihood blind deconvolution of images acquired through scattering media, Proc. Int'l Symposium on Biomedical Imaging (ISBI), 2004 details

    Quasi maximum likelihood blind deconvolution of images acquired through scattering media

    A. M. Bronstein, M. M. Bronstein, M. Zibulevsky, Y. Y. Zeevi
    Proc. Int'l Symposium on Biomedical Imaging (ISBI), 2004

    We address the problem of restoration of images obtained through a scattering medium. We present an efficient quasi-maximum likelihood blind deconvolution approach based on the fast relative Newton algorithm and optimal distribution shaping approach (sparsification), which allows to use simple and convenient sparsity prior for a wide class of images. Simulation results prove the efficiency of the proposed method.