155,869 research outputs found
Smooth Adjustment for Correlated Effects
This paper considers a high dimensional linear regression model with
corrected variables. A variety of methods have been developed in recent years,
yet it is still challenging to keep accurate estimation when there are complex
correlation structures among predictors and the response. We propose an
adaptive and "reversed" penalty for regularization to solve this problem. This
penalty doesn't shrink variables but focuses on removing the shrinkage bias and
encouraging grouping effect. Combining the l_1 penalty and the Minimax Concave
Penalty (MCP), we propose two methods called Smooth Adjustment for Correlated
Effects (SACE) and Generalized Smooth Adjustment for Correlated Effects
(GSACE). Compared with the traditional adaptive estimator, the proposed methods
have less influence from the initial estimator and can reduce the false
negatives of the initial estimation. The proposed methods can be seen as linear
functions of the new penalty's tuning parameter, and are shown to estimate the
coefficients accurately in both extremely highly correlated variables situation
and weakly correlated variables situation. Under mild regularity conditions we
prove that the methods satisfy certain oracle property. We show by simulations
and applications that the proposed methods often outperforms other methods
Meromorphic differentials with twisted coefficients on compact Riemann surfaces
This note is to concern a generalization to the case of twisted coefficients
of the classical theory of Abelian differentials on a compact Riemann surface.
We apply the Dirichlet's principle to a modified energy functional to show the
existence of differentials with twisted coefficients of the second and third
kinds under a suitable assumption on residues.Comment: 20 page
Sparse Laplacian Shrinkage with the Graphical Lasso Estimator for Regression Problems
This paper considers a high-dimensional linear regression problem where there
are complex correlation structures among predictors. We propose a
graph-constrained regularization procedure, named Sparse Laplacian Shrinkage
with the Graphical Lasso Estimator (SLS-GLE). The procedure uses the estimated
precision matrix to describe the specific information on the conditional
dependence pattern among predictors, and encourages both sparsity on the
regression model and the graphical model. We introduce the Laplacian quadratic
penalty adopting the graph information, and give detailed discussions on the
advantages of using the precision matrix to construct the Laplacian matrix.
Theoretical properties and numerical comparisons are presented to show that the
proposed method improves both model interpretability and accuracy of
estimation. We also apply this method to a financial problem and prove that the
proposed procedure is successful in assets selection
Computational multiheterodyne spectroscopy
Dual comb spectroscopy allows for high-resolution spectra to be measured over
broad bandwidths, but an essential requirement for coherent integration is the
availability of a phase reference. Usually, this means that the combs' phase
and timing errors must be measured and either minimized by stabilization or
removed by correction, limiting the technique's applicability. In this work, we
demonstrate that it is possible to extract the phase and timing signals of a
multiheterodyne spectrum completely computationally, without any extra
measurements or optical elements. These techniques are viable even when the
relative linewidth exceeds the repetition rate difference, and can tremendously
simplify any dual comb system. By reconceptualizing frequency combs in terms of
the temporal structure of their phase noise, not their frequency stability, we
are able to greatly expand the scope of multiheterodyne techniques
First-principles study of two-dimensional van der Waals heterojunctions
Research on graphene and other two-dimensional (2D) materials, such as
silicene, germanene, phosphorene, hexagonal boron nitride (h-BN), graphitic
carbon nitride (g-C3N4), graphitic zinc oxide (g-ZnO) and molybdenum disulphide
(MoS2), has recently received considerable interest owing to their outstanding
properties and wide applications. Looking beyond this field, combining the
electronic structures of 2D materials in ultrathin van der Waals
heterojunctions has also emerged to widely study theoretically and
experimentally to explore some new properties and potential applications beyond
their single components. Here, this article reviews our recent theoretical
studies on the structural, electronic, electrical and optical properties of 2D
van der Waals heterojunctions using density functional theory calculations,
including the Graphene/Silicene, Graphene/Phosphorene, Graphene/g-ZnO,
Graphene/MoS2 and g-C3N4/MoS2 heterojunctions. Our theoretical simulations,
designs and calculations show that novel 2D van der Waals heterojunctions
provide a promising future for electronic, electrochemical, photovoltaic,
photoresponsive and memory devices in the experiments.Comment: 12 pages, 5 figures in Computational Materials Science (2015). arXiv
admin note: text overlap with arXiv:1411.035
Learning Belief Networks in Domains with Recursively Embedded Pseudo Independent Submodels
A pseudo independent (PI) model is a probabilistic domain model (PDM) where
proper subsets of a set of collectively dependent variables display marginal
independence. PI models cannot be learned correctly by many algorithms that
rely on a single link search. Earlier work on learning PI models has suggested
a straightforward multi-link search algorithm. However, when a domain contains
recursively embedded PI submodels, it may escape the detection of such an
algorithm. In this paper, we propose an improved algorithm that ensures the
learning of all embedded PI submodels whose sizes are upper bounded by a
predetermined parameter. We show that this improved learning capability only
increases the complexity slightly beyond that of the previous algorithm. The
performance of the new algorithm is demonstrated through experiment.Comment: Appears in Proceedings of the Thirteenth Conference on Uncertainty in
Artificial Intelligence (UAI1997
Effects of Pressure on the Electronic Structures of LaOFeP
We studied the electronic structures of LaOFeP under applied pressure using
first-principles calculations. The electronic density of states at the Fermi
level decreases continuously with increasing pressure. The electron branches of
Fermi surfaces are rather robust to pressure, while the hole branches change
significantly. Two hole surfaces shrink into small ellipsoid-like surfaces and
disappear finally, at which the applied pressure is ~ 74.7 GPa. The pressure
response can be understood by the band structures around the Fermi level.
Comparative studies reveal that the disappearance of hole surfaces is mainly
due to the compression of the FeP layer along the c-axis of unit cell.Comment: 26 pages, 9 figure
Semi-continuity for total dimension divisors of \'etale sheaves
In this article, we extend a pull-back inequality for total dimension
divisors of \'etale sheavs due to Saito. Using this formula, we generalize
Deligne and Laumon's lower semi-continuous property for Swan conductors of
\'etale sheaves on relative curves to higher relative dimensions in a geometric
situation.Comment: 16 pages. Improve the writing in the new versio
Weierstrass Semigroups from Kummer Extensions
The Weierstrass semigroups and pure gaps can be helpful in constructing codes
with better parameters. In this paper, we investigate explicitly the minimal
generating set of the Weierstrass semigroups associated with several totally
ramified places over arbitrary Kummer extensions. Applying the techniques
provided by Matthews in her previous work, we extend the results of specific
Kummer extensions studied in the literature. Some examples are included to
illustrate our results.Comment: 12 page
Defect in Phosphorene
Defects are inevitably present in materials and always can affect their
properties. Here, first-principles calculations are performed to systematically
study the stability, structural and electronic properties of ten kinds of point
defects in semiconducting phosphorene, including the Stone-Wales (SW-1 and
SW-2) defect, single (SV59 and SV5566) and double vacancy (DV585-1, DV585-2,
DV555777-1, DV555777-2, DV555777-3 and DV4104) defects. We find that these
defects are all much easily created in phosphorene with higher areal density
compared with graphene and silicene. They are easy distinguish each other and
correlate with their defective atomic structures with simulated scanning
tunneling microscopy images at positive bias. The SW, DV585-1, DV555777 and
DV4104 defects have little effect on phosphorene's electronic properties and
defective phosphorene monolayers still show semiconducting with similar band
gap values to perfect phosphorene. The SV59 and DV585-2 defects can introduce
unoccupied localized states into phosphorene's fundamental band gap.
Specifically, the SV59 and 5566 defects can induce hole doping in phosphorene,
and only the stable SV59 defect can result in local magnetic moments in
phosphorene different from all other defects.Comment: 5 pages, 4 figure
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