Your search keyword '"Kenyeres P"' showing total 8 results

1. Distributed Aggregate Function Estimation by Biphasically Configured Metropolis-Hasting Weight Model

Author

M. Kenyeres, J. Kenyeres, V. Skorpil, and R. Burget

Subjects

Distributed computing, aggregate function, average consensus algorithm, metropolis-hasting weight model, wireless sensor networks, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

An energy-efficient estimation of an aggregate function can significantly optimize a global event detection or monitoring in wireless sensor networks. This is probably the main reason why an optimization of the complementary consensus algorithms is one of the key challenges of the lifetime extension of the wireless sensor networks on which the attention of many scientists is paid. In this paper, we introduce an optimized weight model for the average consensus algorithm. It is called the Biphasically configured Metropolis-Hasting weight model and is based on a modification of the Metropolis-Hasting weight model by rephrasing the initial configuration into two parts. The first one is the default configuration of the Metropolis-Hasting weight model, while, the other one is based on a recalculation of the weights allocated to the adjacent nodes’ incoming values at the cost of decreasing the value of the weights of the inner states. The whole initial configuration is executed in a fully-distributed manner. In the experimental section, it is proven that our optimized weight model significantly optimizes the Metropolis-Hasting weight model in several aspects and achieves better results compared with other concurrent weight models.

Published

2017

2. The Distributed Convergence Classifier Using the Finite Difference

Author

M. Kenyeres, J. Kenyeres, and V. Skorpil

Subjects

Distributed computing, wireless sensor networks, average consensus, distributed classifier, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The paper presents a novel distributed classifier of the convergence, which allows to detect the convergence/the divergence of a distributed converging algorithm. Since this classifier is supposed to be primarily applied in wireless sensor networks, its proposal makes provision for the character of these networks. The classifier is based on the mechanism of comparison of the forward finite differences from two consequent iterations. The convergence/the divergence is classifiable only in terms of the changes of the inner states of a particular node and therefore, no message redundancy is required for its proper functionality.

Published

2016

3. Split Distributed Computing in Wireless Sensor Networks

Author

M. Kenyeres, J. Kenyeres, and V. Skorpil

Subjects

Wireless sensor networks, distributed computing, improvement of distributed computing, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

We designed a novel method intended to improve the performance of distributed computing in wireless sensor networks. Our proposed method is designed to rapidly increase the speed of distributed computing and decrease the number of the messages required for a network to achieve the desired result. In our analysis, we chose Average consensus algorithm. In this case, the desired result is that every node achieves the average value calculated from all the initial values in the reduced number of iterations. Our method is based on the idea that a fragmentation of a network into small geographical structures which execute distributed calculations in parallel significantly affects the performance.

Published

2015

4. Connectivity-Based Self-Localization in WSNs

Author

J. Kenyeres, M. Kenyeres, M. Rupp, and P. Farkas

Subjects

WSN, distributed algorithms, border nodes, virtual coordinates, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Efficient localization methods are among the major challenges in wireless sensor networks today. In this paper, we present our so-called connectivity based approach i.e, based on local connectivity information, to tackle this problem. At first the method fragments the network into larger groups labeled as packs. Based on the mutual connectivity relations with their surrounding packs, we identify border nodes as well as the central node. As this first approach requires some a-priori knowledge on the network topology, we also present a novel segment-based fragmentation method to estimate the central pack of the network as well as detecting so-called corner packs without any a-priori knowledge. Based on these detected points, the network is fragmented into a set of even larger elements, so-called segments built on top of the packs, supporting even more localization information as they all reach the central node.

Published

2013

5. Distributed Aggregate Function Estimation by Biphasically Configured Metropolis-Hasting Weight Model.

Author

KENYERES, Martin, KENYERES, Jozef, SKORPIL, Vladislav, and BURGET, Radim

Subjects

ENERGY conservation, ALGORITHMS, APPROXIMATION algorithms, POWER resources, ENERGY consumption

Abstract

An energy-efficient estimation of an aggregate function can significantly optimize a global event detection or monitoring in wireless sensor networks. This is probably the main reason why an optimization of the complementary consensus algorithms is one of the key challenges of the lifetime extension of the wireless sensor networks on which the attention of many scientists is paid. In this paper, we introduce an optimized weight model for the average consensus algorithm. It is called the Biphasically configured Metropolis-Hasting weight model and is based on a modification of the Metropolis-Hasting weight model by rephrasing the initial configuration into two parts. The first one is the default configuration of the Metropolis-Hasting weight model, while, the other one is based on a recalculation of the weights allocated to the adjacent nodes' incoming values at the cost of decreasing the value of the weights of the inner states. The whole initial configuration is executed in a fully-distributed manner. In the experimental section, it is proven that our optimized weight model significantly optimizes the Metropolis-Hasting weight model in several aspects and achieves better results compared with other concurrent weight models. [ABSTRACT FROM AUTHOR]

Published

2017

6. The Distributed Convergence Classifier Using the Finite Difference.

Author

KENYERES, Martin, KENYERES, Jozef, and SKORPIL, Vladislav

Subjects

DISTRIBUTED computing, STOCHASTIC convergence, FINITE differences, ALGORITHMS, WIRELESS sensor networks

Abstract

The paper presents a novel distributed classifier of the convergence, which allows to detect the convergence/ the divergence of a distributed converging algorithm. Since this classifier is supposed to be primarily applied in wireless sensor networks, its proposal makes provision for the character of these networks. The classifier is based on the mechanism of comparison of the forward finite differences from two consequent iterations. The convergence/ the divergence is classifiable only in terms of the changes of the inner states of a particular node and therefore, no message redundancy is required for its proper functionality. [ABSTRACT FROM AUTHOR]

Published

2016

7. Split Distributed Computing in Wireless Sensor Networks.

Author

KENYERES, Martin, KENYERES, Jozef, and SKORPIL, Vladislav

Subjects

DISTRIBUTED computing, WIRELESS sensor networks, ITERATIVE methods (Mathematics), WIRELESS localization, ALGORITHMS

Abstract

We have designed a novel method intended to improve the performance of distributed computing in wireless sensor networks. Our proposed method is designed to rapidly increase the speed of distributed computing and decrease the number of the messages required for a network to achieve the desired result. In our analysis, we chose Average consensus algorithm. In this case, the desired result is that every node achieves the average value calculated from all the initial values in the reduced number of iterations. Our method is based on the idea that a fragmentation of a network into small geographical structures which execute the distributed calculations in parallel significantly affects the performance. [ABSTRACT FROM AUTHOR]

Published

2015

8. Connectivity-Based Self-Localization in WSNs.

Author

KENYERES, Jozef, KENYERES, Martin, RUPP, Markus, and FARKAŠ, Peter

Subjects

WIRELESS sensor networks, WIRELESS sensor nodes, INFORMATION processing, STORAGE fragmentation (Computer science), APRIORI algorithm, LOCALIZATION (Mathematics)

Abstract

Efficient localization methods are among the major challenges in wireless sensor networks today. In this paper, we present our so-called connectivity based approach, i.e, based on local connectivity information, to tackle this problem. At first the method fragments the network into larger groups labeled as packs. Based on the mutual connectivity relations with their surrounding packs, we identify border nodes as well as the central node. As this first approach requires some a-priori knowledge on the network topology, we also present a novel segment-based fragmentation method to estimate the central pack of the network as well as detecting so-called corner packs without any a-priori knowledge. Based on these detected points, the network is fragmented into a set of even larger elements, so-called segments built on top of the packs, supporting even more localization information as they all reach the central node. [ABSTRACT FROM AUTHOR]

Published

2013