Usage of the antenna array for radio communication in locomotive engines in Russian Railways

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Journal of Physics: Conference Series PAPER OPEN ACCESS Usage of the antenna array for radio communication in locomotive engines in Russian Railways To cite this article: Yu O Myakochin 2017 J. Phys.: Conf. Ser. 803 012104 View the article online for updates and enhancements. This content was downloaded from IP address 148.251.232.83 on 16/10/2018 at 15:42

International Conference on Recent Trends in Physics 2016 (ICRTP2016) Journal of Physics: Conference Series 755 (2016) 011001 doi:10.1088/1742-6596/755/1/011001 Usage of the antenna array for radio communication in locomotive engines in Russian Railways Yu O Myakochin 1 1 JSC «ICC Milandr», Georgievskiy prospekt, 5, Zelenograd, Moscow, 124498, Russia. E-mail: myakochin.yuri@ic-design.ru Abstract. The paper presents the realization of the antenna array for arranging the digital communication in the locomotives of Russian Railways. The provided approach allows setting up steady digital communication without expensive updating of the current technique at the substations. The antenna array described in the article has a gain coefficient from 17dB to 18dB at 150MHz. The paper analyzes the data of possible application of digital standards of data transfer without significant modernization of base-load stations used in Russian Railways. 1. Introduction The warrant of the usage of digital radio communication in Russian Railways was issued in 2010 (5 February 5 2010 No. 26), but the switch to the digital standard is not a prompt action. We have two reasons for it - a wide rolling stock and a huge multiple circuit in Russia. But gradually, digital radio communication is spreading by means of purpose-oriented programs of the Russian Federation and by the means of the program of rolling stock modernization. Digital radio communication will allow one to transfer voice and codograms as well as data and telemetry traffic. Besides, remote control over locomotive subsystems will be available. It will give an opportunity to get to a whole new level of information technique in Russian Railways and raise the security of the infrastructure of the rolling stock. In Russian Railways, the changeover to a digital communication is realized by the similar ways as the changeover to the digital radio at long waves where analog communication was also applied. In order to preserve the existing infrastructure (and thus to decrease the cost of the implementation of the new standard), a transfer in the digital channels is realized using the same frequencies as in the analog ones. Hence, it helps to avoid a complete replacement of the expensive transmitting equipment. It is only necessary to correct a baseband signal and leave a power amplifier without changing. The digital radio standard must have the same bandwidth (12kHz) as the analog standard. 2. Advantages of digital communications in the Russian Railways infrastructure and difficulties of its organization The similar approach is used for Russian Railways though there are some peculiarities. The matter is that the dual-range system is used to connect a locomotive with stations: meter-wavelength (150MHz 160MHz) and medium wavelength (2MHz). The changeover to the digital standard will be realized only at the meter wavelength, the medium wavelength remains analog. We have chosen the DMR digital standard. It supports the required functional and operates with 12kHz bandwidth channels (as in Content from this work may be used under the terms of the Creative Commons Attribution 3.0 licence. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI. Published under licence by Ltd 1

the analog mode). Thus, we must organize digital radio at the same frequencies as the former standard. The radio station for the locomotive is an information system which receives data and provides voice communications with subexchange and can handle the components of the locomotive using Ethernet and CAN. Besides, the receiver for GLONASS positioning is embedded in the radio station. Digital standards allow increasing the information capacity of the locomotive quite safely. But the application of the digital standards of the data transmission without complex reconstruction of a baseload station can lead to certain difficulties. The fact is that analog communication is realized even at a small signal-to-noise ratio. It results in the strong noise background, but it is possible to make out the voice because of a good selectivity of a human ear. The situation is different with the digital channel. Voice transmission keeps distinct up to the certain level of a signal-to-noise ratio and then terminates when the modem cannot correct a large number of errors [1]. That is why, it is necessary to improve receiving but at the same time to keep as much of the installed equipment as possible. 3. Analysis of usage of digital standards without complex reconstruction of base-load stations It was offered to increase the gain of the locomotive antenna. Thus, the antenna is the same because the construction has been fine-tuned. The gain is achieved by means of simultaneous usage of several antennas and creating the directed transmitting-receiving system. The unit cells of this system are utilized antennas AL/23 which have good mechanical characteristics. In the horizontal plane, the antenna has a diagram close to the circle diagram with a 78-degree angle. Let us examine the system of two antennas located at the distance of λ/2 with circle diagram patterns as an example. For this two-component system, the normalized directivity coefficient is equal to [2]: The plot gain versus the bearing angle is shown in Figure 1. =cos cos (1) Figure 1. The gain factor of the system of two cophasal components (system 1) Figure 1 shows that maximum gain is achieved in the direction orthogonal to the line of antennas connection. If we place these components along the locomotive than the maximum amplification is attained in the direction orthogonal to the train s movement and it is zero in the line with the train s movement. Thus, this method can be used for the angles in the range of (60;120) degrees. The maximum normalized gain is equal to 1 at 90 degrees, the minimum one is equal to 0.7071 at 60(120) degrees. We need to alter the phase of one of the antennas to 90 degrees in case the directivity is in line with the locomotive movement. Then, the normalized directivity coefficient is estimated as: 2

= cos (2) Figure 2 shows the plot gain versus the bearing angle of this system. Figure 2. The gain factor of the system of two 90-degree shifted components (system 2). For this system, an absolute gain is achieved in the direction of locomotive moving. In the direction orthogonal to the locomotive moving it is equal to zero. This system can be used for the angles in the range of (-60; +60) degrees. Thus, this is the system with the normalized gain from 1 to 0.7071 at any angle. There are possible variants of the usage of system 1 (cophased system) and system 2 (90-degree-shifted) in the table below. Table 1. Possible variants of the usage of system 1 (cophased system) and system 2 (90-degree-shifted) Angle range, degrees Applied system 0 60 System 2 60-120 System 1 120-240 System 2 240-300 System 1 300-360 System 2 The general direction pattern for this system is shown in Figure 3. 3

Figure 3. The direction pattern of the unified system. It is necessary to use several antennas disposed at the distance of λ/2 in order to receive higher amplification levels. The length of the locomotive engines used in Russian Railways does not exceed 18 meters. If carrier frequency is 150MHz, then the distance between antennas is 1 meter. Hence, seventeen antennas can be arranged along the locomotive. These antennas will make system 1 or system 2 as it was demonstrated in the example for two elements. If we deal with system 2, then every second element will be 90-degree phase-shifted. Let us examine system 1 and find its amplification and a beamwidth (by power -3dB). The beamwidth of the antenna array at the 0.7071 level in the azimuth plane is estimated by the following approximation formula [3]: λ 2 2 Qα 51 = 51 = N d 17 1 So the antenna system has a narrow directional pattern and therefore a good gain coefficient: α K = =69 (4) Hereby, the maximum gain coefficient of our system in the direction orthogonal to the train s movement is equal to 69 or 18dB. The directional pattern of the introduced antenna in case of the direction orthogonal to the train s movement is presented in Figure 4. 6 (3) 4

Figure 4. The directional pattern in case of the direction orthogonal to the train s movement. The beamwidth is 7 degrees for the minimum amplification of system 1 (60), thus the gain coefficient is equal to K = =59 (5) In this case, the gain coefficient drops to 59 or 17dB. As a result, we obtained the system with the gain coefficient from 17dB to 18dB. The system must be configured as variant 1(without additional phase shift) or variant 2 (with additional 90-degree phase shift) what depends on the direction. 4. Conclusion For the proper operation of the communication system, it is important to know where the beam of the arranged antenna system must be directed. GLONASS positioning in the locomotive and in the railway map is used for these purposes. When a train is moving on the railway, the angle between the traffic route and the station with the combined antenna is estimated. When the angle has been calculated, then the phased receiving system is adjusted so that the beam points to the station. It will allow increasing the signal-to-noise ratio of the receiving system and thus to realize steady digital communication of the locomotive with the station. So there is no need to change the amplification system at the station what results in the decreasing of the costs of the implementation of digital-speech communication in Russian Railways. 5. Acknowledgement The reported study was funded by the Ministry of Education and Science of the Russian Federation as part of agreement No. 14.579.21.0118 on granting, 27 October, 2016 (unique identifier ASRED RFMEFI57915X0118). References [1] Lyozeen Yu S 1986 Introduction to Theories and Technology of Radiotechnical Systems (M.: - Radio and Communication) [2] Warren L S, Gary A T 2012 Antenna Theory and Design [3] Sklar B 2003 Digital Communications: Fundamentals and Applications (Prentice Hall - PTR) 5

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