KR20100068688A - Repeating method and system by using utp line - Google Patents

Abstract

PURPOSE: A relaying method using a UTP(Unshielded Twisted Pair) line and an apparatus thereof are provided to transmit a mobile communications signal and an internet signal at the same time by connecting a plurality of remote units to the UTP line without establishing a separated line. CONSTITUTION: A main unit(301) transmits a synthetic signal mapped with a time division type to an Ethernet data frame and converts a high frequency signal received from a base station and a communication to a digital signal. A hub(303) transfers the synthetic signal. A remote unit(304,304-1) is connected to a min unit or the hub, separates the Ethernet signal and the digital signal, and outputs the digital signal after converting into the high frequency signal. A transmission line(306) connects the main unit, the hub, and the remote unit.

Description

Repeating method and system by using UTP line

      The present invention relates to a signal processing method of a communication system and an apparatus using the same. More particularly, the present invention relates to a high frequency signal received from a base station or a communication system by a wired or wireless connection to service a mobile communication shadow area occurring in a large building. After converting into a digital signal, the digital signal processing unit maps and transmits it to the Ethernet line in a time division manner so that it is possible to simultaneously transmit the Internet signal and the mobile communication signal using the existing UTP line without expanding a separate line. The present invention relates to a relay method and apparatus using a UTP track.

      Recently, as large scale buildings or high-rise buildings have increased, shadow areas of mobile communication services have occurred in such large buildings. The type of shadow area in such a large building is divided into a case where a part of a large building such as an underground space is not serviced and a part of an upper part of a high-rise building is not serviced. As such, when a large area or a high height of a large shadow area occurs, there is a problem in that a separate repeater or an additional line must be installed in order to solve this problem.

      FIG. 1A illustrates a signal transmission / reception state of a relay device in a base station environment in which a relay device is installed, and a shaded area is generated in an existing service area (shown by a dotted line) of the base station 1 (BTS1) and is signaled by the relay device 100. It shows the case of retransmitting. In general, a cell-type mobile communication system is operated by a method in which a plurality of base stations covering a predetermined area are installed adjacent to each other to reuse an assigned channel frequency. That is, as shown in FIG. 1, base station 2 (BTS2) and base station 3 (BTS3) having respective service areas are adjacent to each other, and although not shown, a plurality of base stations are arranged to establish a communication network. .

      In FIG. 1, when the signal of the base station 1 is retransmitted to the shadow area by using the relay device 100, a signal fB1 of the base station 1 to be retransmitted is basically received by the reception antenna 101 of the relay device. The signal fBIR retransmitted by 102 is sent out, but in an actual propagation environment, the reception antenna 101 is retransmitted to the transmission antenna 102 together with the signals fB2, fB3, ... of other base stations. The received signal fBIR is fed back and received.

      Accordingly, as described above, in the relay apparatus according to the related art, in addition to the signal of the base station to be retransmitted through the receiving antenna, a plurality of unintended signals from other base stations or terminals are mixed or the signal transmitted to the transmitting antenna is fed back. There is a problem that the communication quality is very poor due to the interference signal. That is, in addition to the signal (represented by a solid line) to be retransmitted as shown in FIG. 1, a number of unnecessary signals (indicated by a dotted line) are mixed.

      In addition, Figure 1b is a diagram showing a shadow area occurring in the high-rise portion of the high-rise building. As shown, the existing service area of the base station 1 (BTS1) or the base station 2 (BTS2) is formed as shown by the dotted red line, but when the tall buildings are built in the service area is shaded in the high-rise as shown by the blue dotted line An area will arise.

      On the other hand, Figure 2 is a view showing the internal wireless relay system is installed a repeater according to the prior art. In the conventional relay device as shown in FIG. 2, only one relay device is independently used in a shadow area to be serviced, or a plurality of small shadow areas exist such as a large building 200 adjacent to the shadow area. In this case, a plurality of secondary relays 203, 203-1, 203-2, and 203-3 are used in one main relay 201.

      However, in the above-described method, the cost is increased because the main relay and the sub relay are connected by using the coaxial line 207 and the signal distribution means 206. In addition, since the signal transmitted from the main repeater to the secondary repeater is a high frequency signal or an analog signal converted to an intermediate frequency, not only the transmission loss increases but also the number of additional repeaters that can be expanded is limited. Since unnecessary signals are not removed, there is a problem that call quality is degraded. Moreover, when the large building is a high floor and a large floor area, there is another problem that it is impossible for the secondary repeater to service the entire floor.

      The present invention is to solve the problems of the prior art as described above, by converting a high-frequency signal received from a base station or a communication system by a wired or wireless connection to a digital signal, and then in a time-dividing manner on an Ethernet line by a digital signal processor. This method uses the UTP line which can transmit internet signal and mobile communication signal at the same time by connecting multiple remote units by UTP line, which is a low-cost communication line. The purpose is to provide a relay device.

      To this end, the present invention is to convert the high-frequency signal received from the base station or communication system by a wired or wireless connection to a digital signal in order to service the mobile communication shadow area occurring in a large building, and then the Ethernet data frame by the digital signal processor A main unit 301 which transmits the synthesized signal mapped in a time division manner to the hub and a hub or a remote unit connected to the output terminal thereof, and transmits the synthesized signal connected to the main unit, wherein the remote unit is connected to the output terminal. At least one hub (303, 303-1, 303-2, 303-3) connected thereto and connected to the main unit or hub to separate the Ethernet signal and the digital signal from the synthesized signal and convert the digital signal into a high frequency signal. At least one remote unit 304, 304-1, 304-2 for converting and outputting the converted unit; And a transmission line 306 connecting the main unit and the hub, the main unit and the remote unit, and the hub and the remote units.

      As described above, the present invention converts a high frequency signal received from a base station or a communication system by a wired or wireless connection into a digital signal, and then separates and transmits a separate line by mapping and transmitting the same to the Ethernet line by a digital signal processor. By connecting multiple remote units by the UTP line, which is a low-cost communication line, it is possible to simultaneously transmit internet signals and mobile communication signals. There is an effect that can be applied to a wide range of systems.

      As described above, the present invention converts a high frequency signal received from a base station or a communication system by a wired or wireless connection into a digital signal to serve a mobile communication shadow area occurring in a large building, and then converts the Ethernet signal into a digital signal processor. A main unit 301 which transmits a composite signal mapped in a data frame in a time division manner and has a hub or a remote unit connected to an output terminal thereof; and transmits the synthesized signal connected to the main unit, but remote to the output terminal. At least one hub (303, 303-1, 303-2, 303-3) to which the unit is connected; and connected to the main unit or hub to separate the Ethernet and digital signals from the synthesized signal and convert the digital signal into a high frequency At least one remote unit 304, 304-1, 304-2 for converting the signal into a signal and outputting the signal; And a transmission line 306 connecting the main unit and the hub, the main unit and the remote unit, and the hub and the remote units.

      The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

      3 is a diagram illustrating a relay apparatus using a UTP line according to the present invention. As illustrated, the relay apparatus according to the present invention converts a high frequency signal received from a base station or a communication system by a link antenna 302 or a wired connection into a digital signal, and then time-divids it into a data frame of Ethernet by a digital signal processor. At least one hub (303, 303-) which transmits the composite signal mapped to the at least one main unit (301) to which the hub or the remote unit is connected at its output end, and at which the remote unit is connected to the main unit (30). 1, 303-2, 303-3) and at least one remote unit 304 connected to the main unit or hub to separate the Ethernet signal and the digital signal from the synthesized signal, convert the digital signal into a high frequency signal, and output the high frequency signal. 304-1, 304-2), the main unit and hub, the main unit and remote unit, the hub and The remote units are configured to be connected by a UTP cable, which is a low cost transmission line 306.

      4 is a connection diagram of a relay apparatus using a UTP line according to the present invention. As described above, up to eight hubs or remote units are connected to the main unit 301 by the transmission line 306 (FIG. Up to eight remote units are connected to the hubs 303, 303-1, and 303-2 (see symbol B in Fig. 4). The hubs 303, 303-1, and 303-2 are provided with connectors for relaying two bands (see symbol C in FIG. 4), and the remote units 304 and 304- in the same manner. 1 and 304-2 are also provided with connectors for relaying two bands, and the remote units 304, 304-1 and 304-2 are powered from the main unit or hub without using a separate power source. A power supply connector is further provided to receive the power supply (see symbol D of FIG. 4). In particular, the present invention uses an Unshielded Twisted Pair (UTP) cable that is connected to the RJ45 type connector as a transmission line.

      FIG. 5 is a block diagram illustrating a relaying method using a UTP line according to the present invention, and uses an Ethernet over TDM (EoT) method to combine a high frequency signal and an Internet signal. This EoT allocates and transmits an Ethernet signal (100BASE-TX) to a certain band of a TDM signal (1 Gbit / s) having a certain frame format.

      In FIG. 5, the repeater signal (850 Mbps) passes through the repeater-TDM Mapper / Demapper in the corresponding band of the predetermined TDM signal, and the Ethernet signal (100 Mbps) passes through the EoT Mapper / Demapper in the corresponding band of the predetermined TDM signal. Each is assigned. The TDM Framer / Deframer then transmits these mapped repeater signals and Ethernet signals over the UTP line by the Gigabit Ethernet transceiver.

      On the other hand, the receiving side receives the repeater signal and the Ethernet signal separately by the opposite operation. That is, when transmitting, the repeater-TDM mapper maps the repeater signal, and the EoT mapper maps the Ethernet signal to the corresponding band of the predetermined TDM signal and transmits it by the Ethernet transceiver.In contrast, when receiving, the mapping signal received from the Ethernet transceiver is transmitted. Repeater-TDM Demapper extracts the repeater signal and EoT Demapper extracts the Ethernet signal from the TDM signal.

      According to the relay method using the UTP line according to the present invention as described above, in the EoT block diagram of FIG. 5, the total system speed is 1 Gbps, among which the repeater data transmission capacity and the Ethernet data transmission capacity are 850 Mbps and 100 Mbps, respectively. The overhead transmission capacity for data identification is 50 Mbps.

      6 is a view showing the Ethernet data frame structure of the relay method using the UTP line according to the present invention, Figure 6 (a) shows the frame configuration. As shown in the figure, a TDM frame configuration can be used in the form of arbitrary signals (1 Gbit / s transmission frame) while following the GFP format. The mapping of these Ethernet signals is made into a continuous TDM signal and assigned to a designated timeslot. As a process of multiplexing, a method of mapping an Ethernet signal to a TDM Timeslot using a GFP scheme may be used.

      In the present invention, as shown in Figure 6 (b) uses the GFP method for mapping the Ethernet signal. This Generic Framing Procedure (GFP) is a protocol that maps packet data used in Ethernet over SDH / PDH. Unlike HDLC-based protocols, GFP does not use any specific characteristics for frame delineation, which solves the problems of Byte HDLC. Mapping method.

      FIG. 7 is a diagram illustrating a data frame of a synthesized signal of the relay method using the UTIP line according to the present invention. As shown, the repeater data is 850 Mbps and the Ethernet data is 100 Mbps, and the configuration of the data frame of the synthesized signal according to the present invention is as follows. First, Over Head is TXEN_LOW (16B) + Preamble (7B) + SFD (1B) + DCC (1B) = 25B, Payload is 19B × 25 = 475B, so Over Head Rate is 25 / (475 + 25) = 0.05 or 50 Mbps. In addition, Ethernet data is used between the repeater data in the entire frame.

      8 is a view showing the functional configuration of a repeater using a UTP track according to the present invention. As shown, the EoT data path is divided into 100 Mbit / s capacity, and the repeater data path is divided into 850 Mbit / s capacity, and further 50 Mbit / s capacity is allocated to the repeater data path as an overhead for identification. Is sent through. In addition, although the speed of the repeater data is set to 850 Mbps in the embodiment of the present invention, the repeater data capacity is variable according to the change of the overhead data capacity.

      The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

1A is a diagram illustrating a signal transmission and reception state of a relay device in a base station environment in which a relay device is installed.

1B is a view showing a shaded area occurring in a high rise part of a high rise building.

Figure 2 is a diagram showing a premises wireless relay system in which the relay device according to the prior art is installed.

3 is a view showing a repeater using a UTP track according to the present invention.

Figure 4 is a connection diagram of the repeater using the UTP line in accordance with the present invention.

Figure 5 is a block diagram showing a relay method using a UTP track according to the present invention.

6 is a view showing an Ethernet data frame structure of the relay method using a UTIP line according to the present invention.

7 is a view showing a data frame of a composite signal of the relay method using a UTIP line according to the present invention.

8 is a view showing a functional configuration of a repeater using a UTP track according to the present invention.

* Explanation of symbols for the main parts of the drawings

100. Repeater 101. Receiving Antenna

102. Transmission antennas 200, 300. Large buildings

201.Main repeater 202. First antenna

203, 203-1, 203-2, 203-3. First to nth part repeater

204. Second antenna 205. Terminal

206. Signal distribution means 207. Coaxial track

301. Main Unit 302. Link Antenna

303, 303-1, 303-2, 303-3. 1st to nth expansion unit

304, 304-1, 304-2. 1st to nth remote unit

304. Terminal 306. Transmission line

Claims (3)

An apparatus for processing and retransmitting a signal received by a wired or wireless connection, The high frequency signal received from the base station or the communication system by a wired or wireless connection is converted into a digital signal, and then mapped and transmitted to the Ethernet line by a digital signal processor in a time division manner, and the mapped signal transmitted through a UTIP line Relay method using UTP line which separates and receives internet signal and mobile communication signal from signal. An apparatus for processing and retransmitting a signal received by a wired or wireless connection, Converts high frequency signals received from base stations or communication systems to digital signals by wire or wireless connection, and then transmits the composite signals mapped by Ethernet to the data frames of Ethernet in a time-divided manner by the digital signal processor. One main unit to which is connected; and  At least one hub connected to the main unit to transmit the synthesized signal, the remote unit being connected to an output terminal thereof; and At least one remote unit connected to the main unit or hub and separating the Ethernet signal and the digital signal from the synthesized signal, and converting the digital signal into a high frequency signal and outputting the digital signal; And And a transmission line for connecting the main unit and the hub, the main unit and the remote unit, and the hub and the remote units. The method of claim 2, And a transmission line connecting the main unit and the hub, the main unit and the remote unit, and the hub and the remote unit is a UTP cable.

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