82,413 research outputs found
An improved EM algorithm for solving MLE in constrained diffusion kurtosis imaging of human brain
The displacement distribution of a water molecular is characterized
mathematically as Gaussianity without considering potential diffusion barriers
and compartments. However, this is not true in real scenario: most biological
tissues are comprised of cell membranes, various intracellular and
extracellular spaces, and of other compartments, where the water diffusion is
referred to have a non-Gaussian distribution. Diffusion kurtosis imaging (DKI),
recently considered to be one sensitive biomarker, is an extension of diffusion
tensor imaging, which quantifies the degree of non-Gaussianity of the
diffusion. This work proposes an efficient scheme of maximum likelihood
estimation (MLE) in DKI: we start from the Rician noise model of the signal
intensities. By augmenting a Von-Mises distributed latent phase variable, the
Rician likelihood is transformed to a tractable joint density without loss of
generality. A fast computational method, an expectation-maximization (EM)
algorithm for MLE is proposed in DKI. To guarantee the physical relevance of
the diffusion kurtosis we apply the ternary quartic (TQ) parametrization to
utilize its positivity, which imposes the upper bound to the kurtosis. A
Fisher-scoring method is used for achieving fast convergence of the individual
diffusion compartments. In addition, we use the barrier method to constrain the
lower bound to the kurtosis. The proposed estimation scheme is conducted on
both synthetic and real data with an objective of healthy human brain. We
compared the method with the other popular ones with promising performance
shown in the results
Dark Matter as a Possible New Energy Source for Future Rocket Technology
Current rocket technology can not send the spaceship very far, because the
amount of the chemical fuel it can take is limited. We try to use dark matter
(DM) as fuel to solve this problem. In this work, we give an example of DM
engine using dark matter annihilation products as propulsion. The acceleration
is proportional to the velocity, which makes the velocity increase
exponentially with time in non-relativistic region. The important points for
the acceleration are how dense is the DM density and how large is the
saturation region. The parameters of the spaceship may also have great
influence on the results. We show that the (sub)halos can accelerate the
spaceship to velocity . Moreover, in case there is
a central black hole in the halo, like the galactic center, the radius of the
dense spike can be large enough to accelerate the spaceship close to the speed
of light.Comment: 7 pages, 6 figures; v2, minor correction, add the discussion in
annihilation spee
Large Margin Softmax Loss for Speaker Verification
In neural network based speaker verification, speaker embedding is expected
to be discriminative between speakers while the intra-speaker distance should
remain small. A variety of loss functions have been proposed to achieve this
goal. In this paper, we investigate the large margin softmax loss with
different configurations in speaker verification. Ring loss and minimum
hyperspherical energy criterion are introduced to further improve the
performance. Results on VoxCeleb show that our best system outperforms the
baseline approach by 15\% in EER, and by 13\%, 33\% in minDCF08 and minDCF10,
respectively.Comment: submitted to Interspeech 2019. The code and models have been release
Adaptive Stochastic Gradient Langevin Dynamics: Taming Convergence and Saddle Point Escape Time
In this paper, we propose a new adaptive stochastic gradient Langevin
dynamics (ASGLD) algorithmic framework and its two specialized versions, namely
adaptive stochastic gradient (ASG) and adaptive gradient Langevin
dynamics(AGLD), for non-convex optimization problems. All proposed algorithms
can escape from saddle points with at most iterations, which is
nearly dimension-free. Further, we show that ASGLD and ASG converge to a local
minimum with at most iterations. Also, ASGLD with full
gradients or ASGLD with a slowly linearly increasing batch size converge to a
local minimum with iterations bounded by , which
outperforms existing first-order methods.Comment: 24 pages, 13 figure
The Origin of Weak Lensing Convergence Peaks
Weak lensing convergence peaks are a promising tool to probe nonlinear
structure evolution at late times, providing additional cosmological
information beyond second-order statistics. Previous theoretical and
observational studies have shown that the cosmological constraints on
and are improved by a factor of up to ~ 2 when peak
counts and second-order statistics are combined, compared to using the latter
alone. We study the origin of lensing peaks using observational data from the
154 deg Canada-France-Hawaii Telescope Lensing Survey. We found that while
high peaks (with height >3.5 , where is
the r.m.s. of the convergence ) are typically due to one single massive
halo of ~, low peaks ( <~ ) are
associated with constellations of 2-8 smaller halos (<~). In
addition, halos responsible for forming low peaks are found to be significantly
offset from the line-of-sight towards the peak center (impact parameter >~
their virial radii), compared with ~0.25 virial radii for halos linked with
high peaks, hinting that low peaks are more immune to baryonic processes whose
impact is confined to the inner regions of the dark matter halos. Our findings
are in good agreement with results from the simulation work by Yang el al.
(2011).Comment: 10 pages, 10 figures; v2 matches PRD accepted version, results
unchange
Bayesian model-based spatiotemporal survey design for log-Gaussian Cox process
In geostatistics, the design for data collection is central for accurate
prediction and parameter inference. One important class of geostatistical
models is log-Gaussian Cox process (LGCP) which is used extensively, for
example, in ecology. However, there are no formal analyses on optimal designs
for LGCP models. In this work, we develop a novel model-based experimental
design for LGCP modeling of spatiotemporal point process data. We propose a new
spatially balanced rejection sampling design which directs sampling to
spatiotemporal locations that are a priori expected to provide most
information. We compare the rejection sampling design to traditional balanced
and uniform random designs using the average predictive variance loss function
and the Kullback-Leibler divergence between prior and posterior for the LGCP
intensity function. Our results show that the rejection sampling method
outperforms the corresponding balanced and uniform random sampling designs for
LGCP whereas the latter work better for models with Gaussian models. We perform
a case study applying our new sampling design to plan a survey for species
distribution modeling on larval areas of two commercially important fish stocks
on Finnish coastal areas. The case study results show that rejection sampling
designs give considerable benefit compared to traditional designs. Results show
also that best performing designs may vary considerably between target species
Scanning Tunneling Microscope Nanolithography on SrRuO3 Thin Film Surfaces
Nanoscale lithography on SrRuO3 (SRO) thin film surfaces has been performed
by scanning tunneling microscopy under ambient conditions. The depth of etched
lines increases with increasing bias voltage but it does not change
significantly by increasing the tunneling current. The dependence of line width
on bias voltage from experimental data is in agreement with theoretical
calculation based on field-induced evaporation. Moreover, a three-square
nanostructure was successfully created, showing the capability of fabricating
nanodevices in SRO thin films.Comment: 10 pages, 6 figure
Vanilla Lasso for sparse classification under single index models
This paper study sparse classification problems. We show that under
single-index models, vanilla Lasso could give good estimate of unknown
parameters. With this result, we see that even if the model is not linear, and
even if the response is not continuous, we could still use vanilla Lasso to
train classifiers. Simulations confirm that vanilla Lasso could be used to get
a good estimation when data are generated from a logistic regression model
On the Hausdorff dimension faithfulness connected with -expansion
In this paper, we show that, the family of all possible union of finite
consecutive cylinders of the same rank of -expansion is faithful
for the Hausdorff dimension calculation. Applying this result, we give the
necessary and sufficient condition for the family of all cylinders of
-expansion to be faithful for Hausdorff dimension calculation on
the unit interval, this answers the open problem mentioned in a paper of S.
Albeverio et al..Comment: 10 page
Pre-equilibrium dynamics and heavy-ion observables
To bracket the importance of the pre-equilibrium stage on relativistic
heavy-ion collision observables, we compare simulations where it is modeled by
either free-streaming partons or fluid dynamics. These cases implement the
assumptions of extremely weak vs. extremely strong coupling in the initial
collision stage. Accounting for flow generated in the pre-equilibrium stage, we
study the sensitivity of radial, elliptic and triangular flow on the switching
time when the hydrodynamic description becomes valid. Using the hybrid code
iEBE-VISHNU we perform a multi-parameter search, constrained by particle
ratios, integrated elliptic and triangular charged hadron flow, the mean
transverse momenta of pions, kaons and protons, and the second moment of the proton transverse momentum spectrum, to identify optimized
values for the switching time from pre-equilibrium to hydrodynamics,
the specific shear viscosity , the normalization factor of the
temperature-dependent specific bulk viscosity , and the switching
temperature from viscous hydrodynamics to the hadron cascade
UrQMD. With the optimized parameters, we predict and compare with experiment
the -distributions of , , , , and
yields and their elliptic flow coefficients, focusing specifically on the
mass-ordering of the elliptic flow for protons and Lambda hyperons which is
incorrectly described by VISHNU without pre-equilibrium flow.Comment: 4 pages, 1 figure. Talk presented at Quark Matter 2015, Kobe, Sep. 27
- Oct. 3, 2015, to appear in the proceedings published by Nuclear Physics A.
v2 corrects originally mislabeled curves in Figs. 2a,
- β¦