KR101719955B1 - Repeating system using leakage coaxial cable and ics repeater in tunnel - Google Patents

Abstract

Disclosed is a relay system using a leakage cable and an ICS repeater in tunnel. The relay system comprises: a RF coupler (200) which is coupled to the leakage cable to receive a radio frequency (RF) signal from the leakage cable on a line of the leakage cable (10), wherein the line of the leakage cable is not an end point of the leakage cable; and a ICS repeater (100) which is connected to the RF coupler by a cable, and amplifies the RF signal of the leakage cable which is received through the RF coupler.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a repeating system using a leakage cable and an ICS repeater in a tunnel,

The present invention relates to a relay system using a leakage cable and an ICS repeater in a tunnel, and more particularly, to a relay system for an RF signal used in a railway, etc., To a relay system.

For the maintenance and management of railways and roads, which are designated as domestic industry, a separate frequency is designated in the country and a communication system using the designated frequency is constructed and used. In particular, telecommunication services in the tunnel section have played an important role in obtaining and protecting lives in the event of a fire or an accident rather than maintenance and management aspects.

However, in the current communication system in the tunnel, there are two types of communication methods, short-duplex and duplex, and there are many long-distance tunnels longer than 2 km, and there are many shaded areas where communication service is not smooth in the tunnel.

Particularly, due to the special circumstances inside the tunnel, there is not much developed a relay system for use in a tunnel. Up to now, a leakage coaxial cable (hereinafter, simply referred to as a "leakage cable" Quot;) is used as it is. An example of an in-tunnel relay system related to a leakage cable is disclosed in Korean Patent Publication No. 2000-0019793 (published on Apr. 15, 2000).

BACKGROUND ART In a conventional wireless communication in connection with a leakage cable in a tunnel, a method in which a main device located in a waiting room and a terminal located in a tunnel communicate wirelessly using a leakage cable installed in the tunnel is used. Therefore, the size of a signal generated in a terminal, the size of a signal generated in a main equipment located in a waiting room, a line loss of a leakage cable installed in a tunnel, and a spatial loss lost due to propagation in a space are important Element.

Especially, in case of railway tunnels, as mentioned above, it is often several kilometers, and when the length of the tunnel is more than 2 km, the communication using the leakage cable has a weak signal, There is a feature that communication is not made.

In addition, existing leakage cables installed in tunnels are connected to only one line without connection points, making it difficult to add new equipment such as repeaters in the middle.

Therefore, in order to solve the problem of shaded area in railroad communication used in railway tunnels, new equipment such as a repeater capable of amplifying a weak signal without distortion of a signal is needed, and a new leakage It is necessary to develop a relay system of a new structure so that the cable can be installed without any damage and can be operated.

Korean Patent Publication No. 2000-0019793 (published April 15, 2000)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a relay system using a leakage cable and an ICS repeater to solve the problem of a shadow area without damaging an existing leakage cable installed in a tunnel.

According to one aspect of the present invention, there is provided a relay system using a leakage cable and an ICS repeater in a tunnel, wherein a line of the leakage cable has an end point of the leakage cable An RF coupler 200 coupled to the leakage cable to receive a radio frequency (RF) signal from the leakage cable, and an RF coupler 200 coupled to the RF coupler and received through the RF coupler, And an ICS repeater 100 for amplifying RF signals from the ICS repeater 100.

According to one embodiment, the RF coupler includes a coupling antenna unit 210 connected to the leakage cable, and fixing members 220 and 230 for fixing the coupling antenna unit in a tunnel.

According to one embodiment, the coupling antenna unit 210 includes a helical antenna 214 for receiving an RF signal from the leakage cable, and a case 216 surrounding the helical antenna, When coupling the antenna portion with the leakage cable, the coupling antenna portion is bent along the circumference of the leakage cable to be coupled to the leakage cable.

According to one embodiment, the fixing members 220 and 230 include a fixing plate 220 fixed to the inner wall of the tunnel, the fixing plate being grounded, A socket member 230 on which an antenna coupling terminal 236a for coupling to the ICS repeater 100 and an amplifier connecting terminal 236b for a wired connection to the ICS repeater 100 are formed; And an internal connector 234 for electrically connecting the terminals.

According to one embodiment, the ICS repeater 100 may be configured such that the signal by the feedback loop contained in the RF signal from the leakage cable, the signal by the feedback loop, is the gain (G) of the ICS repeater 100 A cancellation signal generator 120 for generating a cancellation signal for canceling a leakage current generated when the leakage cable is larger than the isolation of the leakage cable; A first transmission antenna Tx1 and a second transmission antenna Tx2 for transmitting a signal amplified by the amplification circuit unit, and a second transmission antenna Tx2 for amplifying the signal amplified by the amplification circuit unit, Tx2) - the first transmission antenna and the second transmission antenna transmit signals amplified by the amplification circuit part in opposite directions to each other; A first barrier rib 160b for isolating between the first transmission antenna and the second transmission antenna and a second barrier 160a for isolating between the amplification circuit part and the first transmission antenna and between the amplification circuit part and the second transmission antenna, .

According to one embodiment, the first bank and the second bank are made of a metal material.

According to one embodiment, the outer wall of the ICS repeater 100 has a portion adjacent to the first transmission antenna and the second transmission antenna is made of a non-metallic material, and the remaining portion is made of a metal material.

The present invention provides a relay system in which an ICS repeater is added without damaging an existing leakage cable in a tunnel, thereby solving the problem of a shade area which is a disadvantage of in-tunnel communication using only existing leakage cables, So that it can be easily installed without damage.

FIG. 1 is a longitudinal sectional view, FIG. 2 is a side sectional view corresponding to FIG. 1, and FIG. 2 is a cross-
3 is a view for explaining an oscillation phenomenon caused by a feedback loop, which is a problem that may occur when a general repeater 40 having a gain G is applied to a leakage cable,
FIG. 4 is a view for explaining an effect of applying an ICS repeater according to an embodiment of the present invention, which is different from the general repeater 40 of FIG. 3, to a leakage cable,
5 is a block diagram showing detailed components of the ICS repeater of FIG. 4,
6 is a view for explaining the detailed configuration of an ICS repeater 100 and an RF coupler 200 of a relay system according to an embodiment of the present invention,
7 is a view showing a state in which the ICS repeater 100 and the RF coupler 200 of FIG. 6 are installed on the side wall 3 of the tunnel and are coupled to the leakage cable 10,
8 is a detailed configuration diagram of the coupling antenna unit 210 of the RF coupler 200,
9 is a view showing a state 200b in which the coupling antenna unit 210 is bent using a heating device to fix the coupling antenna unit 210 so as to be wound around the leakage cable,
10 is an internal layout view of important components of an ICS repeater 100 according to an embodiment of the present invention.

FIG. 1 is a longitudinal sectional view, FIG. 2 is a side sectional view corresponding to FIG. 1, and FIG. 3 is a cross sectional view of a gain FIG. 4 is a view for explaining an oscillation phenomenon caused by a feedback loop, which is a problem that may occur when a general repeater 40 having a gain of G is applied to a leakage cable. FIG. FIG. 5 is a block diagram showing the detailed components of the ICS repeater of FIG. 4, and FIG. 6 is a block diagram of the ICS repeater according to an embodiment of the present invention. 6 is a view for explaining the detailed configuration of an ICS repeater 100 and an RF coupler 200 of a relay system according to an embodiment of the present invention. FIG. 7 is a view for explaining an ICS repeater 100 and an RF coupler 200 of FIG. (3) of the side wall 8 is a detailed configuration diagram of the coupling antenna unit 210 of the RF coupler 200 and FIG. 9 is a view illustrating a state where the coupling antenna unit 210 is connected to the leakage cable 10, And FIG. 10 is an internal layout view of important components of the ICS repeater 100 according to an embodiment of the present invention. FIG. 10 is a plan view showing a bent state 200b using a heating device .

First, referring to FIGS. 1 and 2, a leakage cable 10 installed in a tunnel is used. The leakage cable 10 is connected to the leakage cable 10 by wire, and the transmission and reception antennas 20a and 30a are connected to each other. There is shown an RF repeater 20, 30 for transmitting an RF signal to the main equipment (not shown). 1 and 2, the communication between the terminal located in the tunnel 4 and the external main equipment (not shown) relies solely on the leakage cable 10 installed along the side wall 3 of the tunnel Therefore, as mentioned above, there are many shaded areas that can not communicate within the tunnel. Particularly, when the length of the tunnel is long, this phenomenon becomes more serious and it becomes difficult to provide smooth communication service in the tunnel. 1, reference numeral 1 denotes a railway line, and reference numeral 2 denotes India.

Next, in order to solve the problem of the translucent area in the communication using the leakage cable 10 in the tunnel, the case of using a general repeater having a gain of G and the case of using an ICS (Interference Cancellation System) 5 and Fig. 5. In FIGS. 3 and 4, ISO represents the isolation between leaky cables.

3, when the signal s1 indicated by (1) is input from the leakage cable 10 to the general repeater 40 side, the general repeater 40 amplifies the signal s1 The signal s2 is transmitted to the terminal inside the tunnel in the same manner as the signal s2 indicated by (2), and at the same time, the signal s2 affects the side of the leakage cable 10 as indicated by (3). Accordingly, although the gain G of the general repeater 40 is larger than the isolation degree ISO, a signal due to the feedback loop is generated, although it depends on the isolation (ISO) of the leakage cable. The signal fs1 generated by the feedback loop is generated as shown in (5) and (4), and accordingly, in the left leakage cable 10, in addition to the signal s1 to be amplified, And then goes out to the general repeater 40 side. Accordingly, the general repeater 40 amplifies the signal fs1 due to the feedback loop, which is a meaningless signal, and sends it to the terminal in the tunnel. In addition, the repeater 40 repeats a continuous infinite feedback loop, .

In contrast, when the ICS (Interference Cancellation System) repeater is applied as shown in FIG. 4, the self-oscillation problem as shown in FIG. 3 can be solved. 4, when the signal s1 indicated by (1) is inputted from the leakage cable 10 to the ICS repeater 100 side, the ICS repeater 100 amplifies the signal so that the signal s2 shown in (2) At the same time, this signal s2 also affects the side of the leakage cable 10 as indicated by (3). Accordingly, although the gain G of the ICS repeater 100 is greater than the isolation degree ISO, a signal due to the feedback loop is generated, although it depends on the isolation (ISO) of the leakage cable. The signal fs1 due to the feedback loop is generated in the left leakage cable 10 as shown in (5), and the signal fs1 due to the feedback loop is generated in addition to the signal s1 to be amplified, And the ICS repeater 100 side. This process is similar to the case of using the general repeater 40 of FIG. In the ICS repeater 100, when the signal fs1 due to the feedback loop is mixed together with the signal s1 to be amplified as shown in (5), the ICS repeater 100 generates a cancellation signal generation algorithm in the ICS repeater 100 The signal fs1 due to the feedback loop is canceled and then transmitted to the terminal in the tunnel at s3 as shown in (6). By eliminating the signal fs1 by the feedback loop by this canceling signal generation algorithm, the self-oscillation problem in the case of employing a general repeater in the leakage cable can be solved. Therefore, the relay system of the present invention adopts the ICS repeater 100 as described above.

5 shows a principle of eliminating the signal fs1 by the feedback loop using the vector synthesis with the cancellation signal cs1 generated by the cancellation signal generator 120 of the ICS repeater 100 of Fig. Brief Description of Drawings Fig. 5, the ICS repeater 100 includes a signal (fs1) generated by a feedback loop received through a reception antenna Rx (indicated by (1) and (3) in FIG. 5) The signal transmitted to the transmitting antenna Tx is converted into an analog to digital (ATD) signal by the amplifier circuit 110, and then the amplified signal is transmitted through the transmitting antenna Tx. (A), a phase (?), And a time deviation (D) of a signal fs1 by a feedback loop mixed in an original signal s1 by a DSP (Digital Signal Process) And the cancellation signal cs1 is generated using the factors in the cancellation signal generation algorithm 121. [ The cancel signal cs1 has the same amplitude as the signal fs1 by the feedback loop shown in (1), but its phase is opposite (indicated by ②). Also, the delay of the amplifying circuit unit 110 itself is taken into account for the time deviation (D). Then, the original signal s1 mixed with the signal fs1 by the feedback loop is vector-synthesized with the cancellation signal cs1 using the vector synthesizer 140, and the resultant signal And s3 indicated by (5) are transmitted to the terminal receiving the RF signal service through the transmission antenna Tx. Referring to FIG. 5, a recursive least square (RLS) method and a least mean square (LMS) method can be applied as a process of generating a cancellation signal. Such a method may be performed by a person skilled in the art Is well known to.

As described above with reference to FIG. 3 to FIG. 5, when an ICS repeater is applied to a leakage cable in a tunnel, the self-oscillation problem can be solved by removing a signal due to a feedback loop , And this ICS repeater is employed in the present invention.

In addition, when it is desired to apply the ICS repeater to the leakage cable 10 in the tunnel, it is required to apply the leakage cable 10 without damaging the installed leakage cable 10. In view of this, the RF coupler 200, The relay system including the ICS repeater 100 is implemented.

Referring to FIG. 6, there is shown a relay system 100, 200 of a relay system according to an embodiment of the present invention. Referring to FIG. 6, a relay system 10 using a leakage cable 10 in a tunnel according to the present invention, An RF coupler 200 coupled to the leakage cable 10 on the line of the leakage cable 10 to receive a radio frequency (RF) signal for receiving an RF (Radio Frequency) signal from the leakage cable 10, For amplifying the RF signal from the leakage cable 10 connected to the RF coupler 200 by wire and receiving the RF signal through the RF coupler 200 and providing the amplified RF signal to a terminal (not shown) And an ICS repeater 100. The RF coupler 200 is connected to the coupling portion 210 of the leakage cable 10 by using the coupling antenna portion 210 as described below on the line of the leakage cable 10, do. Therefore, in the present invention, there is no damage to the already installed leakage cable 10 itself.

7, which is a diagram showing a state in which the RF coupler 200 is actually applied to the inner side wall 3 of the tunnel, will be described with reference to FIG. 6. In the ICS repeater 100, The RF signal from the leakage cable 10 is amplified and transmitted to the terminal side. The RF signal is provided to the terminal after removing the signal by the feedback loop using the cancellation signal generation algorithm.

The RF coupler 200 includes a coupling antenna unit 210 connected to the leakage cable 10 and fixing members 220 and 230 for fixing the coupling antenna unit 210 in the tunnel.

8, the coupling antenna unit 210 includes a helical antenna 214 for receiving an RF signal from the leakage cable 10, a case 216 for enclosing the outside of the helical antenna 214, ). 9, when the coupling antenna unit 210 is coupled to the leakage cable 10, the coupling antenna unit 200 is connected to the upper portion of the leakage cable 10 from 200a to 200b, And is coupled to the leakage cable 10 in a bent state along the circumference. A portion of the coupling antenna unit 210 coupled to the fixing members 220 and 230 may have a helical structure such as 212 to facilitate coupling to the fixing members 220 and 230.

Generally, there are many kinds of antennas used in wireless communication. However, the antennas employed in the coupling antenna unit 210 of the present invention are inexpensive, have good characteristics even at low frequencies, An easy helical antenna 214 is used. 8 and 9, the helical antenna 214 is an antenna manufactured using a conductor line as long as the wavelength (?) Length of a signal, and can be formed into a spring shape so that the shape of the antenna can be easily modified There is an advantage. In addition, the RF connector having the helical structure 212 is formed by winding a line in the form of a spring by a length of a wavelength to match the frequency characteristics, and then the outer portion is wrapped around the case 216 and finished. . As the material of the case, PC (polycarbonate) may be used, but it is not limited to these materials. In addition, in FIG. 9, in order to bend the shape to 200b, it is possible to easily bend using a heating tool such as a lighter or a torch.

6 and 7, the fixing members 220 and 230 include a fixing plate 220 fixed to the inner wall 3 of the tunnel, a socket member 230 extending from the fixing plate 220, And an internal connector 234 for electrical connection within the socket member 230.

The fixing plate 220 and the socket member 230 may be integrally formed with each other or may be individually manufactured as shown and joined together through various bonding methods such as welding or bonding. The fixing plate 220 is preferably grounded. The fixing plate 220 is fixed to the side wall of the tunnel through a fixing hole 222 formed in the fixing plate 220 such as a pit or bolt.

The socket member 230 includes an antenna coupling terminal 236a for screwing the coupling antenna unit 210 and an amplifier connection terminal 236a for wired connection to the ICS repeater 100 using the cable 150. [ (236b) are formed. A connector 152 is formed so that the terminal of the cable 150 connected to the ICS repeater 100 side can be connected to the amplifier connection terminal 236b side of the socket member 230. [

The internal connector 234 electrically connects the antenna coupling terminal 236a and the amplifier coupling terminal 236b. Connector terminals 234a and 234b are formed at both ends of the internal connector 234 to correspond to the antenna coupling terminal 236a and the amplifier coupling terminal 236b, respectively.

Next, an example of the ICS repeater 100 will be described with reference to FIGS. 4 and 5 together with FIG.

The ICS repeater 100 includes a canceling signal generator 120 (FIG. 5) for generating a cancellation signal cs1 for canceling a signal due to a feedback loop contained in an RF signal from a leakage cable, An amplification circuit unit 110 for amplifying a signal resulting from eliminating a feedback loop signal from an RF signal from the leakage cable using the cancellation signal cs1, And a first transmission antenna Tx1 and a second transmission antenna Tx2 for transmitting signals. Although the cancel signal generator 120 is not shown in FIG. 10, it may be considered that the cancel signal generator 120 is located adjacent to the amplifier circuit 110.

The transmission antennas, i.e., the first transmission antenna Tx1 and the second transmission antenna Tx2 transmit signals amplified by the amplification circuitry 110 in mutually opposite directions to extend the communication coverage, .

The ICS repeater 100 includes a first barrier 160b for isolating a first transmission antenna Tx1 and a second transmission antenna Tx2 and includes an amplifier circuit 110 and a first transmission antenna Tx1 And a second barrier 160a for isolating between the amplification circuit unit 110 and the second transmission antenna Tx2. The first barrier ribs 160a and the second barrier ribs 210b are preferably made of a metal material so as to facilitate isolation.

The outer wall 170a of the portion adjacent to the first transmission antenna Tx1 and the outer wall 170b of the portion adjacent to the second transmission antenna Tx2 are formed at the entire outer walls 160c, 170a, and 170b of the ICS repeater 100, Is formed of a nonmetallic material so that the first transmission antenna Tx1 and the second transmission antenna Tx2 can be transmitted to the terminal receiving the service without being lost by the outer walls 170a and 170b of the adjacent portion of the RF signal And the remaining outer wall portion 160c is preferably made of a metal material for shielding. The remaining outer wall portion 160c is preferably grounded for the bias of the first transmission antenna Tx1 and the second transmission antenna Tx2.

As described above, the present invention provides a relay system in which an ICS repeater is added without damaging existing leakage cables in a tunnel, thereby solving the problem of a shadow area, which is a disadvantage of in-tunnel communication using only existing leakage cables You can easily install additional, without damaging the leakage cable. Particularly, the underground railway space is an environment in which the internal space is not wide enough to easily allow addition of various equipment, so that the relay system of the present invention will provide a solution that can be easily installed in such a special environment.

100: ICS repeater
200: RF coupler
210: Coupling antenna part
214: Helical antenna
216: Case
220: Fixing plate
230: socket member
234: Internal connector

Claims (7)

A relay system using a leakage cable in a tunnel,
An RF coupler coupled to the leakage cable to receive an RF (Radio Frequency) signal from the leakage cable, the RF coupler coupled to the leakage cable, (200); And
And an ICS repeater (100), which is connected to the RF coupler by wires, for amplifying an RF signal from the leakage cable received through the RF coupler,
The RF coupler includes a coupling antenna unit 210 connected to the leakage cable and fixing members 220 and 230 for fixing the coupling antenna unit in a tunnel, A helical antenna 214 for receiving an RF signal from the leakage cable, and a case 216 surrounding the helical antenna. When coupling the coupling antenna with the leakage cable, And the upper portion is bent along the circumference of the leakage cable to be coupled to the leakage cable. delete delete [2] The apparatus according to claim 1, wherein the fixing members (220, 230)
A fixed plate 220 fixed to a side wall of the tunnel, the fixed plate being grounded,
A socket member 230 extending from the fixed plate and having an antenna coupling terminal 236a for threading the coupling antenna unit and an amplifier connection terminal 236b for wired connection to the ICS repeater 100, Wow,
And an internal connector (234) for electrically connecting the antenna connection terminal and the amplifier connection terminal. The ICS repeater (100) according to claim 1,
The signal by the feedback loop contained in the RF signal from the leakage cable-the signal by the feedback loop occurs when the gain G of the ICS repeater 100 is greater than the isolation of the leakage cable. - a cancellation signal generator 120 for generating a cancellation signal for canceling -
An amplifier circuit 110 for amplifying a signal resulting from eliminating a feedback loop signal from an RF signal from the leakage cable using the cancellation signal,
A first transmission antenna (Tx1) and a second transmission antenna (Tx2) for transmitting a signal amplified by the amplification circuit part, the first transmission antenna and the second transmission antenna being arranged in opposite directions to each other, And transmitting the amplified signal,
A first barrier 160b for isolating the first transmission antenna and the second transmission antenna,
And a second partition (160a) for isolating between the amplification circuit part and the first transmission antenna, and between the amplification circuit part and the second transmission antenna. The relay system according to claim 5, wherein the first partition and the second partition are made of a metal material. 7. The relay system according to claim 6, characterized in that an outer wall of the ICS repeater (100) is made of a nonmetallic material and the remaining portion is made of a metal material, the portion adjacent to the first transmission antenna and the second transmission antenna .

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