Modelado de sensores basado en la Arquitectura MDA para microrredes eléctricas
Vol. 6 Núm. 6 (2016), Artículos
Vol. 6 Núm. 6 (2016)

Modelado de sensores basado en la Arquitectura MDA para microrredes eléctricas

Artículos
https://doi.org/10.15765/e.v6i6.836
Publicado 2016-10-13
Elvis Eduardo Gaona García
Laboratorio de Investigación en Fuentes Alternativas de Energía, Departamento de Ingeniería Eléctrica, Universidad Distrital Francisco José de Caldas
Cesar Leonardo Trujillo Rodríguez
Laboratorio de Investigación en Fuentes Alternativas de Energía, Departamento de Ingeniería Eléctrica, Universidad Distrital Francisco José de Caldas
Víctor Daniel Angulo Morales
Grupo de Investigación en Telecomunicaciones de la Universidad Distrital, Departamento de Ingeniería Electrónica, Universidad Distrital Francisco José de Caldas
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Palabras clave

redes de sensores inalámbricos
Arquitectura MDA
Microgrilla
sistemas de micro-almacenamiento.

Resumen

En este artículo se propone un modelo basado en la arquitectura MDA (Model Driven Architecture) para el diseño de una red de sensores inalámbricos que monitorea variables de tensión y corriente en una microrred eléctrica. Se describen sus componentes, el módulo sensor, el módulo de procesamiento, y por último el de transmisión de los datos.

También se propone un modelo de toma de decisiones compuesto poruna carga, la red principal y una fuente de generación con un sistema de almacenamiento de energía.

https://doi.org/10.15765/e.v6i6.836
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Citas

H. B. Puttgen, P. R. Macgregor, and F. c. Lambert, “Distributed generation:

Semantic hype or the dawn of a new era?,” Power and Energy Magazine, IEEE, no.

february 2003, p. 8, 2003.

H. Hussein, S. Harb, and N. Kutkut, “Design considerations for distributed microstorage

systems in residential applications,” in Telecommunications Energy Conference

(INTELEC), 32nd International., 2010, p. 6.

R. V. P. Yerra, A. K. Bharathi, P. Rajalakshmi, and U. B. Desai, “WSN based

power monitoring in smart grids,” in Intelligent Sensors, Sensor Networks and

Information Processing (ISSNIP), 2011 Seventh International Conference on, 2011,

pp. 401–406.

N. D. Hatziargyriou, S. Member, I. A. Dimeas, S. M. Ieee, A. G. Tsikalakis, and S.

Member, “Management of Microgrids Environment in Market.”

J. Guerrero, J. Vasquez, J. Matas, L. G. de Vicuña, and M. Castilla, “Hierarchical

control of droop-controlled AC and DC microgrids, A general approach toward

standardization,” Ind. Electron. IEEE Trans., vol. 58, no. 1, pp. 158–172, 2011.

R. Burrett, R. Dixon, M. Eckhart, D. Hales, and A. Kloke-lesch, “Renewable Energy

Policy Network for the 21st Century REN21 Steering Committee,” Paris, 2009.

K. Shenai and K. Shah, “Smart DC micro-grid for efficient utilization of distributed

renewable energy,” Energytech, 2011 IEEE, 2011.

W. Jiang and Y. Zhang, “Load Sharing Techniques in Hybrid Power Systems for

DC Micro-Grids,” in Power and Energy Engineering Conference (APPEEC), 2011,

pp. 1–4.

A. Kwasinski and P. Krein, “A microgrid-based telecom power system using modular

multiple-input dc-dc converters,” in Telecommunications Conference, 2005.

INTELEC’05. Twenty-Seventh International, 2005, pp. 515–520.

J. Quesada, R. Sebastián, M. Castro, and J. a. Sainz, “Control of inverters in a low

voltage microgrid with distributed battery energy storage. Part I: Primary control,”

Electr. Power Syst. Res., vol. 114, pp. 126–135, Sep. 2014.

W. Huang, “Power flow analysis of a grid-connected high-voltage microgrid with

various distributed resources,” in 2011 Second International Conference on Mechanic

Automation and Control Engineering, 2011, pp. 1471–1474.

A. G. Kleppe, J. Warmer, W. Bast, and M. D. A. Explained, The model driven

architecture: practice and promise. Addison-Wesley Longman Publishing Co., Inc.,

Boston, MA, 2003.

C. Hahn, C. Madrigal-Mora, and K. Fischer, “A platform-independent metamodel

for multiagent systems,” Auton. Agent. Multi. Agent. Syst., vol. 18, no. 2, pp.

–266, 2009.

G. Benguria, X. Larrucea, B. Elvesaeter, T. Neple, A. Beardsmore, and M. Friess,

“A platform independent model for service oriented architectures,” in Enterprise

interoperability, Springer, 2007, pp. 23–32.

I. Khemapech, “Feasibility Study of Direct Communication in Wireless Sensor

Networks,” Procedia Comput. Sci., vol. 21, pp. 424–429, Jan. 2013.

F. Escolar, S., Carretero, J., García, F., Isaila, F., “Acabando con los desarrollos

Ad-Hoc en Wireless Sensor Networks,” 2006, p. XVII Jornadas de Paralelismo.

G. Engels, R. Heckel, and J. M. Kuster, “Rule-based specification of behavioral

consistency based on the UML meta-model,” in UML 2001 The Unified Modeling

Language. Modeling Languages, Concepts, and Tools, Springer, 2001, pp. 272–286.

T. C. Rodrigues, P. V. Dantas, F. C. Delicato, P. F. Pires, C. Miceli, and L. Pirmez,

“Using MDA for building wireless sensor network applications,” in Proceedings - 4th

Brazilian Symposium on Software Components, Architectures and Reuse, SBCARS

, 2010, pp. 110–119.

T. Rodrigues, T. Batista, and A. Y. Zomaya, “Model-Driven Approach for Building

Efficient Wireless Sensor and Actuator Network Applications,” pp. 43–48, 2013.

K. Czarnecki and S. Helsen, “Classification of model transformation approaches,”

in Proceedings of the 2nd OOPSLA Workshop on Generative Techniques in the

Context of the Model Driven Architecture, 2003, vol. 45, no. 3, pp. 1–17.

A. Clark and C. J. Pavlovski, “Wireless Networks for the Smart Energy Grid:

Application Aware Networks,” Computer (Long. Beach. Calif)., vol. II, 2010.

W. B. Heinzelman, A. L. Murphy, H. S. Carvalho, and M. A. Perillo, “Middleware

to support sensor network applications,” Network, IEEE, vol. 18, no. 1, pp. 6–14,