Nonlinear Multidimensional Bayesian Estimation with Fourier Densities

Brunn, Dietrich; Sawo, Felix; Hanebeck, Uwe D.

doi:10.1109/cdc.2006.377378

Cited by 12 publications

(16 citation statements)

References 10 publications

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“…[5] and [6] derived the basic operations using Fourier density approximation. Here some important equations related to BP are briefly described.…”

Section: Fourier Density Approximationmentioning

confidence: 99%

“…Recently, [5] and [6] ensured the non-negativity of Fourier series by approximating the square root of the density instead of the density itself. The usage of Fourier series in nonlinear Bayesian filtering is also derived in [5] and [6]. Using Fourier density approximation, the belief can be represented sufficiently by only a small number of Fourier coefficients.…”

Section: Introductionmentioning

confidence: 99%

“…Fourier series were first employed to estimate probability densities in [4]. Recently, [5] and [6] ensured the non-negativity of Fourier series by approximating the square root of the density instead of the density itself. The usage of Fourier series in nonlinear Bayesian filtering is also derived in [5] and [6].…”

Section: Introductionmentioning

confidence: 99%

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Fourier density approximation for belief propagation in wireless sensor networks

Na¹,

Wang²,

Obradović³

et al. 2008

2008 IEEE International Conference on Multisensor Fusion and Integration for Intelligent Systems

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Abstract-Many distributed inference problems in wireless sensor networks can be represented by probabilistic graphical models, where belief propagation, an iterative message passing algorithm provides a promising solution. In order to make the algorithm efficient and accurate, messages which carry the belief information from one node to the others should be formulated in an appropriate format. This paper presents two belief propagation algorithms where non-linear and non-Gaussian beliefs are approximated by Fourier density approximations, which significantly reduces power consumptions in the belief computation and transmission. We use self-localization in wireless sensor networks as an example to illustrate the performance of this method.

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“…[5] and [6] derived the basic operations using Fourier density approximation. Here some important equations related to BP are briefly described.…”

Section: Fourier Density Approximationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Fourier density approximation for belief propagation in wireless sensor networks

Na¹,

Wang²,

Obradović³

et al. 2008

2008 IEEE International Conference on Multisensor Fusion and Integration for Intelligent Systems

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show abstract

“…The partitioning from one layer to the next is similar to n-dimensional Octrees [6] or B-trees [7]. The container structure allows for the use of different density representation forms in the tree nodes, from very simple forms, such as Dirac impulses or uniform distributions, to very elaborate and complex ones, such as Gaussian mixture densities [8] or Fourier densities [9], even mixed in the same tree. This offers a compromise between the number of tree nodes and the number of parameters of individual node functions.…”

Section: Introductionmentioning

confidence: 99%

Density trees for efficient nonlinear state estimation

Eberhardt

Klumpp

Hanebeck

2010

2010 13th International Conference on Information Fusion

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-In this paper, a new class of nonlinear Bayesian estimators based on a special space partitioning structure, generalized Octrees, is presented. This structure minimizes memory and calculation overhead. It is used as a container framework for a set of node functions that approximate a density piecewise. All necessary operations are derived in a very general way in order to allow for a great variety of Bayesian estimators. The presented estimators are especially well suited for multi-modal nonlinear estimation problems. The running time performance of the resulting estimators is first analyzed theoretically and then backed by means of simulations. All operations have a linear running time in the number of tree nodes.

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“…Unfortunately, the resulting Gaussian densities are not capable of representing arbitrary density functions that may appear in estimation problems of arbitrary nonlinear systems. Other density representations include Gaussian mixture densities [7], gridbased approaches [8], simple moments of probability density functions [9], exponential densities [3], fourier series [10], [11], the representation by means of sample sets [12], or Dirac mixture densities [13], which are capable of representing more general densities.…”

Section: Introductionmentioning

confidence: 99%

Direct fusion of Dirac mixture densities using an efficient approximation in joint state space

Klumpp¹,

Hanebeck²

2008

2008 IEEE International Conference on Multisensor Fusion and Integration for Intelligent Systems

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Abstract-In this paper, we present a direct fusion algorithm for processing the combination of two Dirac mixture densities. The proposed approach allows the multiplication of two Dirac mixture densities without requiring identical support and thus enables the fusion of two independently generated sample sets. The resulting posterior Dirac mixture density is an approximation of the true continuous density that would result from the processing of the underlying true continuous density functions. This procedure is based on a suboptimal greedy approximation of the joint state space by means of a Dirac mixture that iteratively increases the resolution of the fusion result while considering only the relevant regions in the joint state space, where the fusion constraint holds.

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Nonlinear Multidimensional Bayesian Estimation with Fourier Densities

Cited by 12 publications

References 10 publications

Fourier density approximation for belief propagation in wireless sensor networks

Fourier density approximation for belief propagation in wireless sensor networks

Density trees for efficient nonlinear state estimation

Direct fusion of Dirac mixture densities using an efficient approximation in joint state space

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