1,615 research outputs found
Frequent Subgraph Mining in Outerplanar Graphs
In recent years there has been an increased interest in frequent pattern discovery in large databases of graph structured objects. While the frequent connected subgraph mining problem for tree datasets can be solved in incremental polynomial time, it becomes intractable for arbitrary graph databases. Existing approaches have therefore resorted to various heuristic strategies and restrictions of the search space, but have not identified a practically relevant tractable graph class beyond trees. In this paper, we define the class of so called tenuous outerplanar graphs, a strict generalization of trees, develop a frequent subgraph mining algorithm for tenuous outerplanar graphs that works in incremental polynomial time, and evaluate the algorithm empirically on the NCI molecular graph dataset
Effective Privacy Amplification for Secure Classical Communications
We study the practical effectiveness of privacy amplification for classical
key-distribution schemes. We find that in contrast to quantum key distribution
schemes, the high fidelity of the raw key generated in classical systems allow
the users to always sift a secure shorter key if they have an upper bound on
the eavesdropper probability to correctly guess the exchanged key-bits. The
number of privacy amplification iterations needed to achieve information leak
of 10^-8 in existing classical communicators is 2 or 3 resulting in a
corresponding slowdown 4 to 8. We analyze the inherent tradeoff between the
number of iterations and the security of the raw key. This property which is
unique to classical key distribution systems render them highly useful for
practical, especially for noisy channels where sufficiently low quantum bit
error ratios are difficult to achieve.Comment: 11 pages, 3 figure
An exactly mass conserving space-time embedded-hybridized discontinuous Galerkin method for the Navier-Stokes equations on moving domains
This paper presents a space-time embedded-hybridized discontinuous Galerkin
(EHDG) method for the Navier--Stokes equations on moving domains. This method
uses a different hybridization compared to the space-time hybridized
discontinuous Galerkin (HDG) method we presented previously in (Int. J. Numer.
Meth. Fluids 89: 519--532, 2019). In the space-time EHDG method the velocity
trace unknown is continuous while the pressure trace unknown is discontinuous
across facets. In the space-time HDG method, all trace unknowns are
discontinuous across facets. Alternatively, we present also a space-time
embedded discontinuous Galerkin (EDG) method in which all trace unknowns are
continuous across facets. The advantage of continuous trace unknowns is that
the formulation has fewer global degrees-of-freedom for a given mesh than when
using discontinuous trace unknowns. Nevertheless, the discrete velocity field
obtained by the space-time EHDG and EDG methods, like the space-time HDG
method, is exactly divergence-free, even on moving domains. However, only the
space-time EHDG and HDG methods result in divergence-conforming velocity
fields. An immediate consequence of this is that the space-time EHDG and HDG
discretizations of the conservative form of the Navier--Stokes equations are
energy stable. The space-time EDG method, on the other hand, requires a
skew-symmetric formulation of the momentum advection term to be energy-stable.
Numerical examples will demonstrate the differences in solution obtained by the
space-time EHDG, EDG, and HDG methods
A locally conservative and energy-stable finite element for the Navier--Stokes problem on time-dependent domains
We present a finite element method for the incompressible Navier--Stokes
problem that is locally conservative, energy-stable and pressure-robust on
time-dependent domains. To achieve this, the space--time formulation of the
Navier--Stokes problem is considered. The space--time domain is partitioned
into space--time slabs which in turn are partitioned into space--time
simplices. A combined discontinuous Galerkin method across space--time slabs,
and space--time hybridized discontinuous Galerkin method within a space--time
slab, results in an approximate velocity field that is -conforming and exactly divergence-free, even on time-dependent domains.
Numerical examples demonstrate the convergence properties and performance of
the method
Analysis of a space--time hybridizable discontinuous Galerkin method for the advection--diffusion problem on time-dependent domains
This paper presents the first analysis of a space--time hybridizable
discontinuous Galerkin method for the advection--diffusion problem on
time-dependent domains. The analysis is based on non-standard local trace and
inverse inequalities that are anisotropic in the spatial and time steps. We
prove well-posedness of the discrete problem and provide a priori error
estimates in a mesh-dependent norm. Convergence theory is validated by a
numerical example solving the advection--diffusion problem on a time-dependent
domain for approximations of various polynomial degree
Construction of Activity-based Anorexia Mouse Models
Anorexia nervosa (AN) is a psychiatric disorder mainly characterized by extreme hypophagia, severe body weight loss, hyperactivity, and hypothermia. Currently, AN has the highest mortality rate among psychiatric illnesses. Despite decades of research, there is no effective cure for AN nor is there a clear understanding of its etiology. Since a complex interaction between genetic, environmental, social, and cultural factors underlines this disorder, the development of a suitable animal model has been difficult so far. Here, we present our protocol that couples a loss-of-function mouse model to the activity-based anorexia model (ABA), which involves self-imposed starvation in response to exposure to food restriction and exercise. We provide insights into a neural circuit that drives survival in AN and, in contrast to previous protocols, propose a model that mimics the conditions that mainly promote AN in humans, such as increased incidence during adolescence, onset preceded by negative energy balance, and increased compulsive exercise. This protocol will be useful for future studies that aim to identify neuronal populations or brain circuits that promote the onset or long-term maintenance of this devastating eating disorder
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