5,463 research outputs found
Controlled imprisonment of wave packet and flat bands in a fractal geometry
The explicit construction of non-dispersive flat band modes and the
tunability of has been reported for a hierarchical 3-simplex fractal geometry.
A single band tight binding Hamiltonian defined for the deterministic
self-similar non-translationally invariant network can give rise to a countably
infinity of such self localized eigenstates for which the wave packet gets
trapped inside a characteristic cluster of atomic sites. An analytical
prescription to detect those dispersionless states has been demonstrated
elaborately. The states are localized over clusters of increasing sizes,
displaying the existence of a multitude of localization areas. The onset of
localization can, in principle, be delayed in space by an appropriate choice of
the energy of the electron. The response of the system with the modulation of
the anisotropy parameter is also studied. Supportive calculation of spectral
landscape and demonstration of band dispersion plot are presented to solidify
the analytical results. Variation of effective mass tensor cites re-entrant
behavior with respect to the modulation of off-diagonal anisotropy. The
tunability of those states leads to the controlled decay of wave function
envelope. The impact of uniform magnetic perturbation on the bound states has
also been discussed. Continuous variation of flux modulates the position of the
flat band modes. The macroscopic degeneracy associated with the modes is
retained with respect to the application of perturbation.Comment: 11 pages; 12 eps figures (Accepted for publication in Physica
Scripta
Analytical study of quasi-one dimensional flat band networks and slow light analogue
Exact method of analytical solution of flat, non-dispersive eigenstates in a
class of quasi-one dimensional structures is reported within the tight-binding
framework. The states are localized over certain sublattice sites. One such
finite size cluster of atomic sites is decoupled from the rest of the system by
the special non-permissible vertex having zero amplitude. This immediately
leads to the self-trapping of the incoming excitation. We work out an
analytical scheme to discern the localizing character of the diffraction free
dispersionless modes using real space renormalization group technique.
Supportive numerical calculations of spectral profile and transport are
demonstrated to substantiate the essence of compact localized states. Possible
experimental scope regarding the photonic analogue of the tight-binding
electronic case is also discussed elaborately. This eventually unfolds the
concepts of slow light and the related re-entrant mode switching from the study
of optical dispersion.Comment: 11 pages, 11 eps figures (Accepted in Acta Physica Polonica A). arXiv
admin note: text overlap with arXiv:1901.0924
An Analytical Study of different Document Image Binarization Methods
Document image has been the area of research for a couple of decades because
of its potential application in the area of text recognition, line recognition
or any other shape recognition from the image. For most of these purposes
binarization of image becomes mandatory as far as recognition is concerned.
Throughout couple decades standard algorithms have already been developed for
this purpose. Some of these algorithms are applicable to degraded image also.
Our objective behind this work is to study the existing techniques, compare
them in view of advantages and disadvantages and modify some of these
algorithms to optimize time or performance.Comment: National Conference on Computing and Communication Systems
(COCOSYS-09), UIT, Burdwan, January 02-04, 2009, pp. 71-7
Engineering flat electronic bands in quasiperiodic and fractal loop geometries
Exact construction of one electron eigenstates with flat, non-dispersive
bands, and localized over clusters of various sizes is reported for a class of
quasi-one dimensional looped networks. Quasiperiodic Fibonacci and Berker
fractal geometries are embedded in the arms of the loop threaded by a uniform
magnetic flux. We work out an analytical scheme to unravel the localized single
particle states pinned at various atomic sites or over clusters of them. The
magnetic field is varied to control, in a subtle way, the extent of
localization and the location of the flat band states in energy space. In
addition to this we show that, an appropriate tuning of the field can lead to a
re-entrant behavior of the effective mass of the electron in a band, with a
periodic flip in its sign.Comment: 9 pages, 8 figure
Flux modulated flat band engineering in square-kagome ladder network
The origin of non-dispersive flat band modes for a quasi-one dimensional
square-kagome ladder network is explored analytically by virtue of the real
space renormalization group (RSRG) technique. A section of the eigenstates is
non-diffusive i.e., localized within a cluster of sub-lattice sites partly by
the destructive type of quantum interference and partly by the physical divider
formed by the sites with zero wave function amplitude. By making the amplitude
vanish at the selective sites it becomes possible to confine the incoming
excitation within the trapping cell leading to the formation of compact
localized states. The effective mass of the particle becomes infinitely large
corresponding to those self-localized modes and hence the mobility of the wave
train becomes vanishingly small. This quenched kinetic energy leads to a
momentum independent contribution to a dispersion curve. The present analysis
is corroborated by numerical calculation of spectral landscape and the
corresponding dispersion profile. The application of uniform magnetic flux may
lead to a comprehensive engineering of the position as well as the curvature of
the band. Also, one-to-one mapping between electronic case and photonic case
within the tight-binding framework helps us to study the photonic localization
in an analogous single mode wave guide system. The concept of slow light
eventually introduces the possibility of spatial compression of light energy.Comment: 10 pages, 12 eps figures (Revision submitted to Physics Letters A
A Data Driven, Zero-Dimensional Time Delay Model with Radiative Forcing for Simulating Global Climate
Several complicated non-linear models exist which simulate the physical
processes leading to fluctuations in global climate. Some of these more
advanced models use observations to constrain various parameters involved.
However, they tend to be very computationally expensive. Also, the exact
physical processes that affect the climate variations have not been completely
comprehended. Therefore, to obtain an insight into global climate, we have
developed a physically motivated reduced climate model. The model utilizes a
novel mathematical formulation involving a non-linear delay differential
equation to study temperature fluctuations when subjected to imposed radiative
forcing. We have further incorporated simplified equations to test the effect
of speculated mechanisms of climate forcing and evaluated the extent of their
influence. The findings are significant in our efforts to predict climate
change and help in policy framing necessary to tackle it
On the joint distribution of an infinite-buffer discrete-time batch-size-dependent service queue with single and multiple vacation
Due to the widespread applicability of discrete-time queues in wireless
networks or telecommunication systems, this paper analyzes an infinite-buffer
batch-service queue with single and multiple vacation where customers/messages
arrive according to the Bernoulii process and service time varies with the
batch-size. The foremost focal point of this analysis is to get the complete
joint distribution of queue length and server content at service completion
epoch, for which first the bivariate probability generating function has been
derived. We also acquire the joint distribution at arbitrary slot. We also
provide several marginal distributions and performance measures for the
utilization of the vendor. Transmission of data through a particular channel is
skipped due to the high transmission error. As the discrete phase type
distribution plays a noteworthy role to control this error, we include
numerical example where service time distribution follows discrete phase type
distribution. A comparison between batch-size dependent and independent service
has been drawn through the graphical representation of some performance
measures and total system cost.Comment: 28 pages, 5 figure
Higher order Soliton Complexes in Coupled Nonlinear Schr\"odinger Equation with Variable Coefficients
We present the explicit dark-bright three soliton solution and the associated
spectral problem for the variable coefficient integrable coupled NLS equation.
Using asymptotic analysis as well as graphical analysis we study the
interactions in soliton complexes. We present a correlation between the soliton
parameters and the interaction pattern in three soliton complexes. Using
asymptotic analysis, we present a few interesting features of complex three
soliton bound state and interaction of dark-bright two soliton complex with a
regular soliton. Using three soliton interactions we have shown that the energy
sharing take place between soliton even when the soliton do not collide with
each other. The results found by us might be useful for the development of
soliton control, all optical gates as well as all optical switching devices. We
hope that the analysis of three soliton complexes would be useful for a better
understanding of soliton interactions in nonlinear fiber as well as in a bulk
medium.Comment: 25 page
Double ring algorithm of solar active region eruptions within the framework of kinematic dynamo model
Recent results indicate that the Babcock-Leighton mechanism for poloidal
field creation plays an important role in the solar cycle. However, modelling
this mechanism has not always correctly captured the underlying physics. In
particular, it has been demonstrated that using a spatially distributed
near-surface alpha-effect to parametrize the Babcock-Leighton mechanism
generates results which do not agree with observations. Motivated by this, we
are developing a physically more consistent model of the solar cycle in which
we model poloidal field creation by the emergence and flux dispersal of
double-rings structures. Here we present preliminary results from this new
dynamo model.Comment: To appear in proceedings of the ISSTP 2012, 4 Pages,3 figure
Forecasting the solar activity cycle: new insights
Having advanced knowledge of solar activity is important because the Sun's
magnetic output governs space weather and impacts technologies reliant on
space. However, the irregular nature of the solar cycle makes solar activity
predictions a challenging task. This is best achieved through appropriately
constrained solar dynamo simulations and as such the first step towards
predictions is to understand the underlying physics of the solar dynamo
mechanism. In Babcock-Leighton type dynamo models, the poloidal field is
generated near the solar surface whereas the toroidal field is generated in the
solar interior. Therefore a finite time is necessary for the coupling of the
spatially segregated source layers of the dynamo. This time delay introduces a
memory in the dynamo mechanism which allows forecasting of future solar
activity. Here we discuss how this forecasting ability of the solar cycle is
affected by downward turbulent pumping of magnetic flux. With significant
turbulent pumping the memory of the dynamo is severely degraded and thus long
term prediction of the solar cycle is not possible; only a short term
prediction of the next cycle peak may be possible based on observational data
assimilation at the previous cycle minimum.Comment: Proc. of IAU Symposium 29
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