18,064 research outputs found
A two-way regularization method for MEG source reconstruction
The MEG inverse problem refers to the reconstruction of the neural activity
of the brain from magnetoencephalography (MEG) measurements. We propose a
two-way regularization (TWR) method to solve the MEG inverse problem under the
assumptions that only a small number of locations in space are responsible for
the measured signals (focality), and each source time course is smooth in time
(smoothness). The focality and smoothness of the reconstructed signals are
ensured respectively by imposing a sparsity-inducing penalty and a roughness
penalty in the data fitting criterion. A two-stage algorithm is developed for
fast computation, where a raw estimate of the source time course is obtained in
the first stage and then refined in the second stage by the two-way
regularization. The proposed method is shown to be effective on both synthetic
and real-world examples.Comment: Published in at http://dx.doi.org/10.1214/11-AOAS531 the Annals of
Applied Statistics (http://www.imstat.org/aoas/) by the Institute of
Mathematical Statistics (http://www.imstat.org
Multilevel Diversity Coding with Secure Regeneration: Separate Coding Achieves the MBR Point
The problem of multilevel diversity coding with secure regeneration (MDC-SR)
is considered, which includes the problems of multilevel diversity coding with
regeneration (MDC-R) and secure regenerating code (SRC) as special cases. Two
outer bounds are established, showing that separate coding of different
messages using the respective SRCs can achieve the
minimum-bandwidth-regeneration (MBR) point of the achievable normalized
storage-capacity repair-bandwidth tradeoff regions for the general MDC-SR
problem. The core of the new converse results is an exchange lemma, which can
be established using Han's subset inequality
Mining Point Cloud Local Structures by Kernel Correlation and Graph Pooling
Unlike on images, semantic learning on 3D point clouds using a deep network
is challenging due to the naturally unordered data structure. Among existing
works, PointNet has achieved promising results by directly learning on point
sets. However, it does not take full advantage of a point's local neighborhood
that contains fine-grained structural information which turns out to be helpful
towards better semantic learning. In this regard, we present two new operations
to improve PointNet with a more efficient exploitation of local structures. The
first one focuses on local 3D geometric structures. In analogy to a convolution
kernel for images, we define a point-set kernel as a set of learnable 3D points
that jointly respond to a set of neighboring data points according to their
geometric affinities measured by kernel correlation, adapted from a similar
technique for point cloud registration. The second one exploits local
high-dimensional feature structures by recursive feature aggregation on a
nearest-neighbor-graph computed from 3D positions. Experiments show that our
network can efficiently capture local information and robustly achieve better
performances on major datasets. Our code is available at
http://www.merl.com/research/license#KCNetComment: Accepted in CVPR'18. *indicates equal contributio
Exact Results of Strongly Correlated Systems at Finite Temperature
Some rigorous conclusions of the Hubbard model, Kondo lattice model and
periodic Anderson model at finite temperature are acquired employing the
fluctuation-dissipation theorem and particle-hole transform. The main
conclusion states that for the three models, the expectation value of will be of order at any finite
temperature.Comment: 8 pages, no figures, LATEX, corrected some typos, to appear in Phys.
Lett.
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