23,207 research outputs found
Classification of meetings and their participants
On the basis of a coding of utterances we investigate ways to classify participants of a meeting. On the basis of a coding of states of a meeting activities during meetings are classified
On Fuzzy Concepts
In this paper we try to combine two approaches. One is the theory of knowledge graphs in which concepts are represented by graphs. The other is the axiomatic theory of fuzzy sets (AFS).
The discussion will focus on the idea of fuzzy concept. It will be argued that the fuzziness of a concept in natural language is mainly due to the difference in interpretation that people give to a certain word. As different interpretations lead to different knowledge graphs, the notion of fuzzy concept should be describable in terms of sets of graphs. This leads to a natural introduction of membership values for elements of graphs. Using these membership values we apply AFS theory as well as an alternative approach to calculate fuzzy decision trees, that can be used to determine the most relevant elements of a concept
On the relation between the base of an EI algebra and word graphs
This paper is an attempt to investigate the possibilities to link algebraic fuzzy set theory with the theory of word graphs. In both theories concepts are studied and concepts can be set in correspondence. This enables to use algebraic results in the context of word graph theory
Mode dispersion and delay characteristics of optical waveguides using equivalent TL circuits
A new analysis leading to an exact and efficient algorithm is presented for calculating directly and without numerical differentiation the mode dispersion characteristics of cylindrical dielectric waveguides of arbitrary refractive-index profile. The new algorithm is based on the equivalent transmission-line (T-L) technique. From Maxwell's equations, we derive an equivalent T-L circuit for a cylindrical dielectric waveguide. Based on the TL-circuit model we derive exact analytic formulas for a recursive algorithm which allows direct calculation of mode delay and dispersion. We demonstrate this technique by calculating the fundamental mode dispersion for step, triangular, and linear chirp optical fiber refractive index profiles. The accuracy of the numerical results is also examined. The proposed algorithm computes dispersion directly from the propagation constant without the need for curve fitting and subsequent successive numerical differentiation. It is exact, rapidly convergent, and it results in savings for both storage memory and computing time
Compressibility of Interacting Electrons in Bilayer Graphene
Using the renormalized-ring-diagram approximation, we study the
compressibility of the interacting electrons in bilayer graphene. The
compressibility is equivalent to the spin susceptibility apart from a constant
factor. The chemical potential and the compressibility of the electrons can be
significantly altered by an energy gap (tunable by external gate voltages)
between the valence and conduction bands. For zero gap and a typical finite gap
in the experiments, we show both systems are stable.Comment: 5 pages, 6 figure
Absence of broken inversion symmetry phase of electrons in bilayer graphene under charge density fluctuations
On a lattice model, we study the possibility of existence of gapped broken
inversion symmetry phase (GBISP) of electrons with long-range Coulomb
interaction in bilayer graphene using both self-consistent Hartree-Fock
approximation (SCHFA) and the renormalized-ring-diagram approximation (RRDA).
RRDA takes into account the charge-density fluctuations beyond the mean field.
While GBISP at low temperature and low carrier concentration is predicted by
SCHFA, we show here the state can be destroyed by the charge-density
fluctuations. We also present a numerical algorithm for calculating the
self-energy of electrons with the singular long-range Coulomb interaction on
the lattice model.Comment: 8 pages, 6 figure
Study of two-dimensional electron systems in the renormalized-ring-diagram approximation
With a super-high-efficient numerical algorithm, we are able to
self-consistently calculate the Green's function in the
renormalized-ring-diagram approximation for a two-dimensional electron system
with long-range Coulomb interactions. The obtained ground-state energy is found
to be in excellent agreement with that of the Monte Carlo simulation. The
numerical results of the self-energy, the effective mass, the distribution
function, and the renormalization factor of the Green's function for the
coupling constants in the range are also presented.Comment: 4 pages, 5 figure
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