Publication:
Ruido e interferencia en canales de comunicaciones por línea de distribución eléctrica

Thumbnail Image
Files

Files

Ruido e interferencia en canales de comunicaciones por líneas de distribución eléctrica.pdf (2.22 MB)
View Statistics
Reference Managers
Mendeley
Indexers
Google Scholar CORE
QR Code
QR Code
Authors

Authors

Paz Penagos, Hernán
Abstract (Spanish)
Muchos son los desafíos que ha presentado la tecnología PLC a la Ingeniería de Comunicaciones, cuando se pretende ofrecer servicios de banda ancha. Uno de ellos es la dificultad para predecir la atenuación de la señal. La razón principal de esta dificultad esta dada por el hecho que el comportamiento del canal es variable en el tiempo y en la frecuencia, y la caracterización del mismo depende de las características físicas y eléctricas de la red la cual a menudo es desconocida. Este artículo presenta una evaluación de los efectos del ruido e interferencia sobre un byte de información transmitido a través de un canal PLC. Las observaciones presentadas podrían ser ayuda adecuada para el diseño de redes PLC para interiores con mejor transferencia de datos y desempeño.
Abstract (English)
Many are the challenges that the PLC technology has presented to the Communications Engineering, when it is intended to offer broadband services. One of them is the difficulty to predict the signal attenuation. The main reason of this difficulty is given by the fact that the behavior of the channel is time and frequency variant, and the characterization of itself depends on the physical and electrical properties of the network which is often unknown. This article presents an evaluation of the noise and interference effects on an information byte transmitted over a PLC channel. The observations presented could be helpful in suitable design of the indoors PLC networks for a better data transfer and throughput.
Extent
17 páginas
URI: https://repositorio.escuelaing.edu.co/handle/001/2343
Collections

Collections

AB - Ecitrónica
References

Fink, D.G. Standard Handbook for Electrical Engineers, Chapter 13-24, McGraw-Hill, 2000.

Dostert, K. Powerline Communications, Prentice-Hall, 2001.

Cheek, R.C. Electrical Transmission and Distribution, Chapter 12, Westinghouse Electric Corporation, 1999.

Platt, G. Domestic Powerline Carrier Communications, Thesis Bachelor of Engineering in Electrical Engineering, October 1999.

Selander, L. Powerline CommunicationsChannel Properties and Communications Strategies, PhD thesis, Lund University, 1999.

Zu b e ri, K.H. Powe rli n e Ca rri e r Communications Systems, MS Thesis, Departament of Microelectronics and Information Technology, Royal Institute of Technology, KTH, 2003.

Dostert, K. EMC Aspects of High Speed Powerline Communications, Proceedings of th 15 International Wroclaw Symposium and Exhibition on Electromagnetic Compatibility, Wroclaw, Poland, June 27-30, 2000.

Dostert, K. Frequency hopping Spreed Spe c trum modulation for Digital Communication sover Electrical Powerlines, IEEE Journal on Selectred areas in Communications, vol. 9, Nº 3, May 1990, Págs. 700-710.

Hooijen, O.G. A Channel model for residential Power Circuit Used as a Digital Communication Medium, IEEE Transaction on Electromagnetic Compatibility, vol. 40, Nº 4, Nov. 1998, Págs. 331-336.

Zimmermann, M. & Dostert, K. A Multipath Model for Powerline Channel, IEEE Transactions on Communications, vol.50, Nº4, April 2002, Págs. 553-559.

Hensen and W. Schulz, Time Dependence of the Channel Characteristics of Low Voltage Power-Lines and its Effects on Hardware Implementation, AEÜ Int'l. J. Electronics and Commun., 2000, 54 (1), pp. 23–32.

T. Banwell and S. Galli, A novel approach to the modeling of the indoor power line channel—Part 1: Circuit analysis and companion model, IEEE Trans. Power Del., vol. 20, no. 2, pp. 655–663, Apr. 2005.

S. Galli and T. Banwell, A novel approach to the modeling of the indoor power line channel—Part 2: Transfer function and its properties,” IEEE Trans. Power Del., vol. 20, no. 3, pp. 1869–1878, Jul. 2005.

T. Sartenaer and P. Delogne, “Powerline cables modeling for broad band communications,” in Proc. Int. Symp. Power Line Commun. Appl., Malmö, Sweden, Apr. 2001, pp. 331–338.

F. Issa and T. Sartenaer et al., “Analysis of power line communication networks using a new approach based on scattering parameters matrix,” in Proc. IEEE Int. Symp. Electromagn. Compatibility, Minneapolis, MN, Aug. 2002, pp. 1043–1047.

Matthias G, Manuel R, and Dostert, K, University of Karlsruhe, Power Line Channel Characteristics and Their Effect on Communication System Design, IEEE Communications Magazine , 2004, pp.78- 86.

N. Pavlidou, A.J. H. Vinck, J. Yazdani and B. Honary, Power Line Communications: State of the Art and Future Trends, IEEE Communications Magazine, April 2003. pp. 34-40.

E. Biglieri, Coding and Modulation for a Horrible Channel, IEEE Commun. Mag., vol. 41, no. 5, May 2003, pp. 92–98

P. Langfeld, The capacity of typical powerline reference channels and strategies for system design. International Symposium on Power-Line Communications and its Applications (ISPLC), Malm¨o, Su´ecia, apr. 2001, pp. 271.278.

K. Dostert, Power lines as high speed data transmission channelsmodelling the physical limits, IEEE 5th International Symposium on Spread Spectrum Techniques and Applications, vol. 2, sep. 1998, pp. 585.589

Frichman, B.D. A Binary Channel Characterization using partitioned Markov Chains, IEEE Transactions Information Theory vol. IT-13, April 1967.

H. Philipps, Modelling of Powerline rd Communication Channels, Proc. 3 Int'l. Symp. Power-Line Communications and its Applications, Lancaster, U.K., Mar. 30–Apr. 1, 1999, pp. 14-21.

J. Anatory, M.M. Kissaka and N.H. Mvungi, Channel Model for Broadband Powerline Communication, IEEE Trans. On Power Delivery, Vol. 1,January 2007, pp. 135-141.

Paz, H. Sistemas de comunicaciones digitales, primera edición, Editorial de la Escuela Colombiana de Ingeniería JULIO GARAVITO, Marzo 2009.

Zimmermann, M. & Dostert, K. Analysis and Modeling of Impulsive Noise in Broadband Powerline Communications. IEEE Transactions Electromagnetic Compatibility. Vol.44, No.1, Feb. 2002. Págs. 249-58

Midleton, D. Canonical Non-Gaussian Models: Their Implications for Measurement and for Prediction Receiver Performance; IEEE Transactions of Communications, vol. COM21, No. 3, August 1979, pp. 20-220.

Yamauchi, K. & Takahashi, N. Parameter measurements of class A interferente on powerline, Transactions IICE, vol.72, Nº1, January 1989, Págs. 7-9.

S. Barmada, A. Musolino, and M. Raugi, Analysis of integrated circuit systems by an innovative wavelet based scattering matrix Approach, IEEE Trans. Adv. Packag., submitted for publication.

J. Kraus y D. Fleisch, Electromagnetismo, Ed. Mc Graw Hill, quinta edición, 2000.

O.J. Hoojean & A.J. Han Vinck, On the Channel Capacity of a European - style Residential Power Circuit. Japan. ISPLC-1998, pp. 31-44.

J.G. Proakis, Digital communications. McGraw-Hill, New York, EEUU, 4th Edition, 2001.

D.V. Sarwate & M.B. Pursley, Crosscorrelation properties of seudorandom and related sequences. Proceedings of the IEEE, 68(5), 1980. pp. 593-619.

S. Verdú, Multiuser detection, Cambridge University Press, Cambridge, Reino Unido, 1998.

R.G. Gallager, Low Density Parity Check Codes, Number 21 in Research monograph series, MIT Press, Cambridge Massachusetts. 1963

M.C. Davey & D.J. Mackay, Low density parity check codes over GP(q), Proceedings of 1998 IEEE Information Theory Workshops, June 1998.

M.G. Luby & M.A. Shokrollahi, Improved low density parity check codes using irregular graphs and belief propagation, Proceedings of the 1998 IEEE International Symposium on Information Theory, Boston, U.S.A, p. 117.

H. Paz, G.D. Castellanos, R.F. Alarcón, V.L. Weiss, A.R. Laverde, J.C. Rodríguez, J.C. y L.A. Rincón. Diseño e implementación de la red domótica para un laboratorio de ingeniería electrónica. Revista de Ingeniería y universidad, Pontificia Universidad Javeriana – Bogotá, Vol. 10, N° 2, JulioDiciembre de 2006, pp. 223 – 231.

H. Paz, Sistema de Comunicación de Datos a través de la Red Eléctrica. Revista de Ingeniería, Universidad de los Andes, Facultad de Ingeniería (Indexada C), N° 18, Noviembre 2003, pp. 136 – 147.