Automatic Analysis, Decomposition and Parallel Optimization of Large Homogeneous Networks

The life of the modern world essentially depends on the work of the large artificial homogeneous networks, such as wired and wireless communication systems, networks of roads and pipelines. The support of their effective continuous functioning requires automatic screening and permanent optimization with processing of the huge amount of data by high-performance distributed systems. We propose new meta-algorithm of large homogeneous network analysis, its decomposition into alternative sets of loosely connected subnets, and parallel optimization of the most independent elements. This algorithm is based on a network-specific correlation function, Simulated Annealing technique, and is adapted to work in the computer cluster. On the example of large wireless network, we show that proposed algorithm essentially increases speed of parallel optimization. The elaborated general approach can be used for analysis and optimization of the wide range of networks, including such specific types as artificial neural networks or organized in networks physiological systems of living organisms.

homogeneous network, decomposition, optimization, distributed computing

1. Awerbuch B., Goldberg A.V., Luby M., Plotkin S. Network decomposition and locality in distributed computation. Proc. of the 30th Annual Symposium on the Foundations of Computer Science (FOCS 89), 1989, pp. 364-369. doi: 10.1109/SFCS.1989.63504

2. Fantauzzi F., Gaivoronski A.A., Messina E. Decomposition Methods for Network Optimization Problems in the Presence of Uncertainty. Network Optimization, 1997, vol. 450, pp. 234-248. doi: 10.1007/978-3-642-59179-2_12

3. An automatic Sector Planning Method. Patent 104581745 A. Application CH 201510069770, filed February 10 2015, issued April 29 2015, 8 p.

4. Friesen A.L., Domingos P. Recursive Decomposition for Nonconvex Optimization. Proceedings of the 24th International Joint Conference on Artificial Intelligence, 2015, pp. 253-259.

5. Li M., Andersen D.G., Smola A.J. Graph Partitioning via Parallel Submodular Approximation to Accelerate Distributed Machine Learning, 2015, preprint arXiv:1505.04636. https://arxiv.org/abs/1505.04636

6. Singha T., Arbogasta J.E., Neagu N. An incremental approach using local-search heuristic for inventoryrouting problem in industrial gases. Computers and Chemical Engineering, 2015, vol. 80, pp. 199–210.

7. Aarts E., Korst J., Michiels W. Simulated Annealing / Search Methodologies: Introductory Tutorials in Optimization and Decision Support Techniques. Springer Science, New York, 2013, pp. 265-285. doi: 10.1007/978-1-4614-6940-7_10

8. Lotfollahzadeh T., Kabiri S., Kalbkhani H., Shayesteh M.G. Femtocell base station clustering and logistic smooth transition autoregressive-based predicted signal-to-interference-plus-noise ratio for performance improvement of two-tier macro / femtocell networks. IET Signal Processing, 2016, vol. 10, issue: 1, pp. 1-11. doi: 10.1049/iet-spr.2014.0265

9. Kumar P., Patil B., Ram S. Selection of Radio Propagation Model for Long Term Evolution (LTE) Network. International Journal of Engineering, 2015, vol. 3, issue 1, pp. 373-379.

10. Kifle D.W., Wegmann B., Viering I., Klein A. Impact of Antenna Tilting on Propagation Shadowing Model. IEEE Conference on Vehicular Technology VTC, 2013, pp. 1-5. doi: 10.1109/VTCSpring.2013.6692585