14,397 research outputs found
A Proximity Indicator for e-Government: The Smallest Number of Clicks
In order to develop an indicator measuring the proximity of e-Government and its different generic functions, we analysed a set of studies that were conducted in the United States and in Europe. We defined 21 elements of measure grouped in six dimensions of proximity and we surveyed the official Websites of the French-speaking Swiss Cantons in 2002 and 2003. We observed that more technical aspects such as navigability were well developed, whereas more âsocio-politicalâ aspects (data protection, access for handicapped) and organisational issues were still in early stages. To conclude this work we give some hints for the application of a methodology based on proximity measurement.e-Government; portals; evaluation; proximity; 3-clicks rule; usability
Gradient Scan Gibbs Sampler: an efficient algorithm for high-dimensional Gaussian distributions
This paper deals with Gibbs samplers that include high dimensional
conditional Gaussian distributions. It proposes an efficient algorithm that
avoids the high dimensional Gaussian sampling and relies on a random excursion
along a small set of directions. The algorithm is proved to converge, i.e. the
drawn samples are asymptotically distributed according to the target
distribution. Our main motivation is in inverse problems related to general
linear observation models and their solution in a hierarchical Bayesian
framework implemented through sampling algorithms. It finds direct applications
in semi-blind/unsupervised methods as well as in some non-Gaussian methods. The
paper provides an illustration focused on the unsupervised estimation for
super-resolution methods.Comment: 18 page
Performance analysis of beamformers using generalized loading of the covariance matrix in the presence of random steering vector errors
Robust adaptive beamforming is a key issue in array applications where there exist uncertainties about the steering vector of interest. Diagonal loading is one of the most popular techniques to improve robustness. In this paper, we present a theoretical analysis of the signal-to-interference-plus-noise ratio (SINR) for the class of beamformers based on generalized (i.e., not necessarily diagonal) loading of the covariance matrix in the presence of random steering vector errors. A closed-form expression
for the SINR is derived that is shown to accurately predict the SINR obtained in simulations. This theoretical formula is valid for any loading matrix. It provides insights into the influence of the loading matrix and can serve as a helpful guide to select it. Finally, the analysis enables us to predict the level of uncertainties up to which robust beamformers are effective and then depart from the optimal SINR
Performance analysis for a class of robust adaptive beamformers
Robust adaptive beamforming is a key issue in array applications where there exist uncertainties about the steering vector of interest. Diagonal loading is one of the most popular techniques to improve robustness. Recently, worst-case approaches which consist of protecting the array's response in an ellipsoid centered around the nominal steering vector have been proposed. They amount to generalized (i.e. non necessarily diagonal) loading of the covariance matrix. In this paper, we present a theoretical analysis of the signal to interference plus noise ratio (SINR) for this class of robust beamformers, in the presence of random steering vector errors. A closed-form expression for the SINR is derived which is shown to accurately predict the SINR obtained in simulations. This theoretical formula is valid for any loading matrix. It provides insights into the influence of the loading matrix and can serve as a helpful guide to select it. Finally, the analysis enables us to predict the level of uncertainties up to which robust beamformers are effective and then depart from the optimal SINR
Steering vector errors and diagonal loading
Diagonal loading is one of the most widely used and effective methods to improve robustness of adaptive beamformers. In this paper, we consider its application to the case of steering vector errors, i.e. when there exists a mismatch between the actual steering vector of interest and the presumed one. More precisely, we address the problem of optimally selecting the loading level with a view to maximise the signal to interference plus noise
ratio in the presence of random steering vector errors. First, we derive an expression for the optimal loading for a given steering vector error and we show that this loading is negative. Next, this optimal loading is averaged with respect to the probability density function of the steering vector errors, yielding a very simple expression for the average optimal loading. Numerical simulations attest to the validity of the analysis and show that diagonal loading with the optimal loading factor derived herein provides a performance close to optimum
Matched subspace detection with hypothesis dependent noise power
We consider the problem of detecting a subspace signal in white Gaussian noise when the noise power may be different under the null hypothesisâwhere it is assumed to be knownâand the alternative hypothesis. This situation occurs when the presence of the signal of interest (SOI) triggers an increase in the noise power. Accordingly, it may be
relevant in the case of a mismatch between the actual SOI subspace and its presumed value, resulting in a modelling error. We derive the generalized likelihood ratio test
(GLRT) for the problem at hand and contrast it with the GLRT which assumes known and equal noise power under the two
hypotheses. A performance analysis is carried out and the distributions of the two test statistics are derived. From this analysis, we discuss the differences between the two detectors and provide explanations for the improved performance of the new detector. Numerical simulations attest to the validity of the analysis
Matched direction detectors
In this paper, we address the problem of detecting a signal whose associated spatial signature is subject to uncertainties, in the presence of subspace interference and broadband noise, and using multiple snapshots from an array of sensors. To account for steering vector uncertainties, we assume that the spatial signature of interest lies in a given linear subspace H while its coordinates in this subspace are unknown. The generalized likelihood ratio test (GLRT) for the problem at hand is formulated. We show that the GLRT amounts to searching for the best direction in the subspace H after projecting out the interferences. The distribution of the GRLT under both hypotheses is derived and numerical simulations illustrate its performance
- âŠ