8,252 research outputs found
Clustering Graduate Theses Based on Key Phrases Using Agglomerative Hierarchical Methods: An Experiment
Document clustering is an important tool for applications such as Web search engines. Document clustering can be defined as the process of organizing documents into groups. The groups thus formed have a high degree of association between members within the same group and a low degree of association between members of different groups. The goal of this paper is to present an experiment on one of the most widely used document clustering algorithms, namely, the agglomerative hierarchical algorithm. In our experiment, two set of graduate theses are clustered based on the key phrases assigned to each document by the author(s). Overall, the clustering results of our clustering scheme are considered to be very good
Object Frequency and Predictability Effects on Eye Fixation Durations in Real-World Scene Viewing
During text reading, the durations of eye fixations decrease with greater frequency and predictability of the currently fixated word (Rayner, 1998; 2009). However, it has not been tested whether those results also apply to scene viewing. We computed object frequency and predictability from both linguistic and visual scene analysis (LabelMe, Russell et al., 2008), and Latent Semantic Analysis (Landauer et al., 1998) was applied to estimate predictability. In a scene-viewing experiment, we found that, for small objects, linguistics-based frequency, but not scene-based frequency, had effects on first fixation duration, gaze duration, and total time. Both linguistic and scene-based predictability affected total time. Similar to reading, fixation duration decreased with higher frequency and predictability. For large objects, we found the direction of effects to be the inverse of those found in reading studies. These results suggest that the recognition of small objects in scene viewing shares some characteristics with the recognition of words in reading
Semantic guidance of eye movements in real-world scenes
AbstractThe perception of objects in our visual world is influenced by not only their low-level visual features such as shape and color, but also their high-level features such as meaning and semantic relations among them. While it has been shown that low-level features in real-world scenes guide eye movements during scene inspection and search, the influence of semantic similarity among scene objects on eye movements in such situations has not been investigated. Here we study guidance of eye movements by semantic similarity among objects during real-world scene inspection and search. By selecting scenes from the LabelMe object-annotated image database and applying latent semantic analysis (LSA) to the object labels, we generated semantic saliency maps of real-world scenes based on the semantic similarity of scene objects to the currently fixated object or the search target. An ROC analysis of these maps as predictors of subjects’ gaze transitions between objects during scene inspection revealed a preference for transitions to objects that were semantically similar to the currently inspected one. Furthermore, during the course of a scene search, subjects’ eye movements were progressively guided toward objects that were semantically similar to the search target. These findings demonstrate substantial semantic guidance of eye movements in real-world scenes and show its importance for understanding real-world attentional control
Decay constants of -wave mesons
Decay constants of -wave mesons are computed in the framework of
instantaneous Bethe-Salpeter method (Salpeter method). By analyzing the parity
and possible charge conjugation parity, we give the relativistic configurations
of wave functions with definite parity and possible charge conjugation parity.
With these wave functions as input, the full Salpeter equations for different
-wave states are solved, and the mass spectra as well as the numerical
values of wave functions are obtained. Finally we compute the leptonic decay
constants of heavy-heavy and heavy-light , and states.Comment: 11 pages,5 tables,version to be published in Phys. Lett.
QoS multicast tree construction in IP/DWDM optical internet by bio-inspired algorithms
Copyright @ Elsevier Ltd. All rights reserved.In this paper, two bio-inspired Quality of Service (QoS) multicast algorithms are proposed in IP over dense wavelength division multiplexing (DWDM) optical Internet. Given a QoS multicast request and the delay interval required by the application, both algorithms are able to find a flexible QoS-based cost suboptimal routing tree. They first construct the multicast trees based on ant colony optimization and artificial immune algorithm, respectively. Then a dedicated wavelength assignment algorithm is proposed to assign wavelengths to the trees aiming to minimize the delay of the wavelength conversion. In both algorithms, multicast routing and wavelength assignment are integrated into a single process. Therefore, they can find the multicast trees on which the least wavelength conversion delay is achieved. Load balance is also considered in both algorithms. Simulation results show that these two bio-inspired algorithms can construct high performance QoS routing trees for multicast applications in IP/DWDM optical Internet.This work was supported in part ny the Program for New Century Excellent Talents in University, the Engineering and Physical Sciences Research Council (EPSRC) of UK under Grant EP/E060722/1, the National Natural Science Foundation of China under Grant no. 60673159 and 70671020, the National High-Tech Reasearch and Development Plan of China under Grant no. 2007AA041201, and the Specialized Research Fund for the Doctoral Program of Higher Education under Grant no. 20070145017
Band-modulation of MgZnO/ZnO Metal-semiconductor-metal Photodetectors
Magnesium (Mg) diffusion behavior on the band modulation of MgxZn1-xO/ZnO metal-semiconductor-metal photodetectors (MSM-PDs) was studied. As the annealing temperature increases, Mg atoms diffuse from MgxZn1-xO into the underlying ZnO layer, which modulates the detection band of the fabricated MSM-PDs from two distinct bands into one band. For the annealing temperature lower than 900 ºC, two detection bands were achieved located in the wavelength region of 280–320 nm and 360–400 nm, attributed to the absorption of the MgxZn1-xO and the ZnO layer, respectively. When the annealing temperature is raised to 900 ºC, the MgxZn1-xO/ZnO bi- layer becomes homogenized into a single MgxZn1-xO layer, leading to only one detection band with a wavelength region of 280–340 nm. In the photoluminescence measurement, the as-deposited MgxZn1-xO/ZnO bi-layer demonstrates two distinct emission peaks located at about 340 and 400 nm for the absorption of the MgxZn1-xO and ZnO layers, whereas only one emission peak of 355 nm was observed in the 900 ºC-annealed MgxZn1-xO/ZnO bi-layer
Performance Study of Strongly Coupled Magnetic Resonance
Strongly Coupled Magnetic Resonance (SCMR) uses electromagnetic resonance in
order to efficiently transfer power wirelessly over mid-range distances. Since
the energy exchange capability of resonant objects higher than non-resonant
objects, strongly coupled systems are able to achieve more efficient energy
transfer than other wireless power transfer systems. The paper presents
detailed experimental and simulated analysis of the performance of the SCMR
system. A prototype of the SCMR system was implemented and experiments were
conducted to analyze the performance of the system. Finally, the resonant
frequency of the system was experimentally verified and the factors influencing
the wireless power transfer were also studie
Low-energy electrodynamics of infinite-layer nickelates: evidence for d-wave superconductivity in the dirty limit
The discovery of superconductivity in infinite-layer nickelates establishes a
new category of unconventional superconductors that share structural and
electronic similarities with cuprates. Despite exciting advances, such as the
establishment of a cuprate-like phase diagram and the observation of charge
order and short-range antiferromagnetic fluctuation, the key issues of
superconducting pairing symmetry, gap amplitude, and superconducting
fluctuation remain elusive. In this work, we utilize static and ultrafast
terahertz spectroscopy to address these outstanding problems. We demonstrate
that the equilibrium terahertz conductivity and nonequilibrium terahertz
responses of an optimally Sr-doped nickelate film ( = 17 K) are in line
with the electrodynamics of -wave superconductivity in the dirty limit. The
gap-to- ratio 2 is extracted to be 3.4,
indicating the superconductivity falls in the weak-coupling regime. In
addition, we observed significant superconducting fluctuation near
, while it does not extend into the deep normal state as
optimally hole-doped cuprates. Our result highlights a new -wave system
which closely resembles the electron-doped cuprates, expanding the family of
unconventional superconductivity in oxides.Comment: 8 pages, 4 figure
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