1,660 research outputs found
Dynamic Modulation Yields One-Way Beam Splitting
This article demonstrates the realization of an extraordinary beam splitter
based on nonreciprocal and synchronized photonic transitions in obliquely
illuminated space-time-modulated (STM) slabs which impart the coherent temporal
frequency and spatial frequency shifts. As a consequence of such unusual
photonic transitions, a one-way beam splitting and amplification is exhibited
by the STM slab. Beam splitting is a vital operation for various optical and
photonic systems, ranging from quantum computation to fluorescence spectroscopy
and microscopy. Despite the beam splitting is conceptually a simple operation,
the performance characteristics of beam splitters significantly influence the
repeatability and accuracy of the entire optical system. As of today, there has
been no approach exhibiting a nonreciprocal beam splitting accompanied with
transmission gain and an arbitrary splitting angle. Here, we show that oblique
illumination of a periodic and semi-coherent dynamically-modulated slab results
in coherent photonic transitions between the incident light beam and its
counterpart space-time harmonic (STH). Such photonic transitions introduce a
unidirectional synchronization and momentum exchange between two STHs with same
temporal frequencies, but opposite spatial frequencies. Such a beam splitting
technique offers high isolation, transmission gain and zero beam tilting, and
is expected to drastically decrease the resource and isolation requirements in
optical and photonic systems. In addition to the analytical solution, we
provide a closed-form solution for the electromagnetic fields in STM
structures, and accordingly, investigate the properties of the wave isolation
and amplification in subluminal, superluminal and luminal ST modulations
Future imaging atmospheric telescopes: performance of possible array configurations for gamma photons in the GeV-TeV range
The future of ground based gamma ray astronomy lies in large arrays of
Imaging Atmospheric Cherenkov Telescopes (IACT) with better capabilities: lower
energy threshold, higher sensitivity, better resolution and background
rejection. Currently, designs for the next generation of IACT arrays are being
explored by various groups. We have studied possible configurations with a
large number of telescopes of various sizes. Here, we present the precision of
source, shower core and energy reconstruction for gamma rays in the GeV-TeV
range for different altitudes of observation. These results were obtained
through tools that we have developed in order to simulate any type of IACT
configuration and evaluate its performance.Comment: 4 pages, 4 figures, Proceedings of the 30th ICRC, Merida, Mexico
(2007
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Secure communication using dynamic VPN provisioning in an Inter-Cloud environment
Most of the current cloud computing platforms offer Infrastructure as a Service (IaaS) model, which aims to provision basic virtualised computing resources as on-demand and dynamic services. Nevertheless, a single cloud does not have limitless resources to offer to its users, hence the notion of an Inter-Cloud enviroment where a cloud can use the infrastructure resources of other clouds. However, there is no common framework in existence that allows the srevice owners to seamlessly provision even some basic services across multiple cloud service providers, albeit not due to any inherent incompatibility or proprietary nature of the foundation technologies on which these cloud platforms are built. In this paper we present a novel solution which aims to cover a gap in a subsection of this problem domain. Our solution offer a security architecture that enables service owners to provision a dynamic and service-oriented secure virtual private network on top of multiple cloud IaaS providers. It does this by leveraging the scalability, robustness and flexibility of peer- to-peer overlay techniques to eliminate the manual configuration, key management and peer churn problems encountered in setting up the secure communication channels dynamically, between different components of a typical service that is deployed on multiple clouds. We present the implementation details of our solution as well as experimental results carried out on two commercial clouds
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Dynamic virtual private network provisioning from multiple cloud infrastructure service providers
The Cloud infrastructure service providers currently provision basic virtualized computing resources as on demand and dynamic services but there is no common framework in existence that allows the seamless provisioning of even these basic services across multiple cloud service providers, although this is not due to any inherent incompatibility or proprietary nature of the foundation technologies on which these cloud platforms are built. We present a solution idea which aims to provide a dynamic and service oriented provisioning of secure virtual private networks on top of multiple cloud infrastructure service providers. This solution leverages the benefits of peer to peer overlay networks, i.e., the flexibility and scalability to handle the churn of nodes joining and leaving the VPNs and can adapt the topology of the VPN as per the requirements of the applications utilizing its intercloud secure communication framework
Nuclear Effects in Neutrino Induced Coherent Pion Production at K2K and MiniBooNE Neutrino Energies
The coherent pion production induced by neutrinos in nuclei is studied using
a delta hole model in local density approximation taking into account the
renormalization of properties in a nuclear medium. The pion absorption
effects have been included in an eikonal approximation. These effects give a
large reduction in the total cross section. The numerical results for the total
cross section are found to be consistent with recent experimental results from
K2K and MiniBooNE collaborations and other older experiments in the
intermediate energy region.Comment: 4pages, 5figure
Window-based Streaming Graph Partitioning Algorithm
In the recent years, the scale of graph datasets has increased to such a
degree that a single machine is not capable of efficiently processing large
graphs. Thereby, efficient graph partitioning is necessary for those large
graph applications. Traditional graph partitioning generally loads the whole
graph data into the memory before performing partitioning; this is not only a
time consuming task but it also creates memory bottlenecks. These issues of
memory limitation and enormous time complexity can be resolved using
stream-based graph partitioning. A streaming graph partitioning algorithm reads
vertices once and assigns that vertex to a partition accordingly. This is also
called an one-pass algorithm. This paper proposes an efficient window-based
streaming graph partitioning algorithm called WStream. The WStream algorithm is
an edge-cut partitioning algorithm, which distributes a vertex among the
partitions. Our results suggest that the WStream algorithm is able to partition
large graph data efficiently while keeping the load balanced across different
partitions, and communication to a minimum. Evaluation results with real
workloads also prove the effectiveness of our proposed algorithm, and it
achieves a significant reduction in load imbalance and edge-cut with different
ranges of dataset
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