Finite-state Markov modeling of tunnel channels in communication-based train control (CBTC) systems

Communication-based train control (CBTC) is gradually adopted in urban rail transit systems, as it can significantly enhance railway network efficiency, safety and capacity. Since CBTC systems are mostly deployed in underground tunnels and trains move in high speed, building a train-ground wireless communication system for CBTC is a challenging task. Modeling the tunnel channels is very important to design and evaluate the performance of CBTC systems. Most of existing works on channel modeling do not consider the unique characteristics in CBTC systems, such as high mobility speed, deterministic moving direction, and accurate train location information. In this paper, we develop a finite state Markov channel (FSMC) model for tunnel channels in CBTC systems. The proposed FSMC model is based on real field CBTC channel measurements obtained from a business operating subway line. Unlike most existing channel models, which are not related to specific locations, the proposed FSMC channel model takes train locations into account to have a more accurate channel model. The distance between the transmitter and the receiver is divided into intervals, and an FSMC model is applied in each interval. The accuracy of the proposed FSMC model is illustrated by the simulation results generated from the model and the real field measurement results.

[1]  P. Takis Mathiopoulos,et al.  Fast simulation of diversity Nakagami fading channels using finite-state Markov models , 2003, IEEE Trans. Broadcast..

[2]  Cecilio Pimentel,et al.  Finite-state Markov modeling of correlated Rician-fading channels , 2004, IEEE Transactions on Vehicular Technology.

[3]  Fredrik Tufvesson,et al.  A statistical model for indoor office wireless sensor channels , 2009, IEEE Transactions on Wireless Communications.

[4]  Yue Ping Zhang Novel model for propagation loss prediction in tunnels , 2003, IEEE Trans. Veh. Technol..

[5]  Victor C. M. Leung,et al.  Distributed sender scheduling for multimedia transmission in wireless mobile peer-to-peer networks , 2009, IEEE Transactions on Wireless Communications.

[6]  Tao Tang,et al.  Cross-Layer Handoff Design in MIMO-Enabled WLANs for Communication-Based Train Control (CBTC) Systems , 2012, IEEE Journal on Selected Areas in Communications.

[7]  P. Sadeghi,et al.  Finite-state Markov modeling of fading channels - a survey of principles and applications , 2008, IEEE Signal Processing Magazine.

[8]  F. Richard Yu,et al.  Distributed Optimal Relay Selection in Wireless Cooperative Networks With Finite-State Markov Channels , 2010, IEEE Transactions on Vehicular Technology.

[9]  John G. Proakis,et al.  Digital Communications , 1983 .

[10]  Ke Guan,et al.  Measurement of Distributed Antenna Systems at 2.4 GHz in a Realistic Subway Tunnel Environment , 2012, IEEE Transactions on Vehicular Technology.

[11]  David R. Anderson,et al.  Model selection and multimodel inference : a practical information-theoretic approach , 2003 .

[12]  Hong Shen Wang,et al.  Finite-state Markov channel-a useful model for radio communication channels , 1995 .

[13]  Y. Hwang,et al.  Enhancement of rectangular tunnel waveguide model , 1997, Proceedings of 1997 Asia-Pacific Microwave Conference.

[14]  S. P. Lloyd,et al.  Least squares quantization in PCM , 1982, IEEE Trans. Inf. Theory.

[15]  R.D. Pascoe,et al.  What is communication-based train control? , 2009, IEEE Vehicular Technology Magazine.

[16]  Tao Tang,et al.  Handoff Performance Improvements in MIMO-Enabled Communication-Based Train Control Systems , 2012, IEEE Transactions on Intelligent Transportation Systems.