KR102158392B1 - Distributed antenna system - Google Patents

Abstract

The present invention provides a master unit capable of transmitting and receiving a communication signal with a base station, a hub unit receiving the communication signal processed by the master unit or transmitting a communication signal to the master unit, and transmitting a communication signal with the hub unit Provides a distributed antenna system capable of receiving power from the hub unit through a remote unit capable of and a photoelectric composite cable connecting the hub unit and the remote unit to each other, and the remote unit do.

Description

Distributed antenna system

An embodiment of the present invention relates to a distributed antenna system (DAS).

Wireless communication refers to a communication method using radio waves, and is generally referred to as RF (Radio Frequency) communication. In wireless communication using radio waves, information to be transmitted is modulated into radio waves to transmit radio waves through a power amplifier (PA), and the radio waves received at the receiving side are demodulated to receive information.

In the case of a two-way wireless communication such as a mobile phone, a transmit frequency and a receive frequency are set separately to enable simultaneous transmission and reception. In addition, the two-way wireless communication system allocates communication channels so that a plurality of users use different communication channels.

In such a wireless communication system, problems such as a limitation of a subscriber capacity and a service area must be considered. To this end, a wireless communication system that is actually implemented divides a service area into several cells to perform communication.

On the other hand, the wireless communication system adjusts cell coverage so that a shadow area does not occur, but in an actual environment, a shadow area occurs due to a building or an underground space. In this case, a relay system is installed in a shaded area to relay signals from the base station to the terminals.

Among these relay systems, the distributed antenna system arranges a number of distributed antennas within the existing cell coverage, so that radio waves are blocked by mountains, buildings, or other topographical features, or in shadow areas where radio waves are difficult to reach, such as tunnels, underground parking lots, and underground shopping malls. It is a device that amplifies the signal so that the signal from the base station can reach the target and serves the shadow area, and connects the signal of the terminal in the shadow area to reach the base station.

The distributed antenna system may be composed of a master hub unit (MU), a hub unit (HU), and a remote unit (RU) to relay a communication signal between a base station and a user terminal. In a conventional distributed antenna system in a 2G/3G environment, there is no service frequency change, but in the current 4G wireless communication environment, a service frequency change of an upper base station system occurs frequently. In this case, it is necessary to manually change the operation mode of the MU connected to the upper base station system. Therefore, the operation mode must be set according to the antenna output frequency pattern of the base station identified in advance by a worker visiting the site. Is likely to be unnecessarily delayed.

In addition, in the related art, while connecting the hub unit and the remote unit with an optical cable, the remote unit has a separate power supply device. In this case, in order to install the remote unit, a separate electrical wiring work must be performed, so additional installation costs are incurred, and there is a problem that a separate UPS for the remote unit must be installed to maintain service in case of power failure.

In order to solve this problem, the hub unit and the remote unit are connected using a UTP cable. The UTP cable has a power line inside and can supply power from the hub unit to the remote unit, so a separate power supply device is not required for the remote unit. However, in the case of a UTP cable, since the signal is transmitted using a conductor line, there is a limitation in the distance that can transmit the signal without loss, and there is a limitation in the power that can be transmitted through the UTP cable, so the output signal of the remote unit is also limited. There was this.

The main object of the present invention is to provide a distributed antenna system capable of automatically setting an operation mode by automatically detecting an output frequency pattern of an upper base station system.

In addition, it is to provide a distributed antenna system in which system installation and maintenance are easy, and a transmission distance of a communication signal is increased.

A communication relay apparatus according to an embodiment of the present invention includes a master unit capable of transmitting and receiving a communication signal with a base station, a hub unit receiving the communication signal processed by the master unit or transmitting a communication signal to the master unit, , A remote unit capable of transmitting and receiving a communication signal to and from the hub unit, and a photoelectric composite cable connecting the hub unit and the remote unit to each other, wherein the remote unit supplies power from the hub unit through the photoelectric composite cable. Can be supplied.

In the present invention, the remote unit may operate with the power supplied from the hub unit without a separate power source.

In the present invention, the hub unit may include a power supply unit capable of supplying power to the remote unit.

In the present invention, the remote unit may receive an optical signal from the hub unit through the photoelectric composite cable and convert the optical signal into an electric signal.

In the present invention, the communication signal may be transmitted and received between the hub unit and the remote unit through the photoelectric composite cable.

In the present invention, the photoelectric composite cable includes an optical cable disposed at the center of the photoelectric composite cable, at least one first power line unit and at least one second power line unit circumscribed and surrounding the optical cable, and the first And a skin layer surrounding the power line units and the second power line units, wherein the optical cable includes a buffer tube disposed at the center of the optical cable, a plastic tube and the plastic tube aggregated in a longitudinal direction around the buffer tube At least one optical fiber unit including an optical fiber core wire mounted therein, and a sheath layer surrounding the optical fiber unit, wherein one of the first power line unit, one of the second power line unit, and one of the optical fiber unit It can be branched and connected to one of the remote units.

In the present invention, the buffer tube may have a diameter that circumscribes each of the at least one optical fiber unit to stably support the optical fiber unit.

In the present invention, the plastic tube may be made of polypropylene (PP), polybutylene terephthalate (PBT), polycarbonate (PC), polyamide (PA), or a combination thereof.

In the present invention, the buffer tube may be made of a foamed plastic resin having a lower strength than the plastic tube.

In the present invention, a waterproof material including a jelly compound, a waterproof powder, a waterproofing yarn, or a combination thereof may be mounted in the plastic tube together with the optical fiber core wire.

In the present invention, the power may be supplied to the remote unit through the power line.

In the present invention, the communication signal may be transmitted and received between the hub unit and the remote unit through the optical cable.

In the present invention, the photoelectric composite cable includes a first power line unit, a second power line unit, and a ground line, an outer skin layer surrounding and circumscribed thereto, and the first power line unit or the second power line unit or the ground line And it may be made of an optical fiber unit inscribed in the outer layer.

In the present invention, the master unit includes an A/D conversion unit that digitally converts an incoming signal from the base station to generate a signal sample, a signal detection unit that determines whether a communication signal is received based on the signal sample, It may include a mode control unit for setting an operation mode based on the determination result of the reception.

In the present invention, a communication method determination unit for determining a communication method of the incoming signal may be further included.

In the present invention, the mode controller may set the operation mode based on whether the communication signal is received and a determination result of the communication method.

In the present invention, the communication method determination unit may determine a communication method of the incoming signal for each service frequency band.

In the present invention, the signal detector may determine whether to receive the communication signal for each service frequency band.

In the present invention, the mode control unit may operate only when the communication signal is received by the signal detection unit.

In the present invention, it may further include a signal input/output unit connected to the base station by wire to transmit and receive the communication signal.

In the present invention, it may further include a photoelectric conversion unit for photoelectric conversion of the communication signal, and an optical transmission unit for transmitting the photoelectrically converted optical signal in the set operation mode.

In the present invention, the signal detector may receive the communication signal when the size of the signal sample is equal to or greater than a preset reference value.

According to an embodiment of the present invention, an operation mode may be automatically set by automatically detecting an output frequency pattern of an upper base station system.

In addition, a separate power supply device is not required for the remote unit. Accordingly, system installation cost is reduced, installation is easy, system maintenance is easy, and high power can be supplied, thereby enabling flexible network design.

1 is a block diagram schematically showing a distributed antenna system according to an embodiment of the present invention.
2 is a schematic diagram of a master unit of a distributed antenna system according to an embodiment of the present invention.
3 is a table showing an example of an operation mode of the master unit shown in FIG. 2.
FIG. 4 is a diagram for describing an operation mode of the master unit shown in FIG. 2.
5 is a block diagram schematically showing a hub unit of a distributed antenna system according to an embodiment of the present invention.
6 is a block diagram schematically showing a remote unit of a distributed antenna system according to an embodiment of the present invention.
7 is a cross-sectional view schematically showing a photoelectric composite cable of a distributed antenna system according to an embodiment of the present invention.
8 is a schematic cross-sectional view of the optical cable shown in FIG. 7.
9 is a cross-sectional view schematically illustrating a photoelectric composite cable according to another modification.
10 is a cross-sectional view schematically illustrating a photoelectric composite cable according to another modification.
11 is a flowchart schematically illustrating a communication signal relay method of a distributed antenna system according to an embodiment of the present invention.

In the present invention, various modifications may be made and various embodiments may be provided. Specific embodiments are illustrated in the drawings and will be described in detail through detailed description. However, this is not intended to limit the present invention to a specific embodiment, it is to be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

In describing the present invention, when it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, numbers (eg, first, second, etc.) used in the description of the present specification are merely identification symbols for distinguishing one component from another component.

In addition, in the present specification, when one component is referred to as "connected" or "connected" to another component, the one component may be directly connected or directly connected to the other component, but specially It should be understood that as long as there is no opposing substrate, it may be connected or may be connected via another component in the middle.

In the present specification, a user terminal is a device that transmits and receives voice or data with other user terminals via a base station or a repeater, for example, a mobile phone, a smart phone, a laptop computer, a digital broadcasting terminal , PDA (Personal Digital Assistants), PMP (Portable Multimedia Player), navigation, and the like.

Hereinafter, with reference to the accompanying drawings will be described in detail for the implementation of the present invention.

1 is a block diagram schematically showing a distributed antenna system according to an embodiment of the present invention.

Referring to FIG. 1, the distributed antenna system according to an embodiment of the present invention amplifies a downlink signal flowing from an upper base station (BS) 100 and relays it to a user equipment (UE). I can. FIG. 1 shows an example of an in-building distributed antenna system for providing wireless communication coverage in a building. The BS 100 is a base station (eNodeB, eNB), and the MU 200 is a master unit. Unit), HU (300) indicates a hub unit (Hub Unit), RU (400) indicates a remote unit (Remote Unit).

A communication signal stream may be transmitted and received between the base station 100 and the master unit 200. In this case, the base station 100 and the master unit 200 are connected through a wired cable such as a coaxial cable, and the communication signal stream may be transmitted/received in the form of an RF signal or an electric signal.

The master unit 200 digitally converts the communication signal transmitted from the base station 100 and transmits it to the hub unit 300 or converts the communication signal transmitted from the hub unit 300 to analog and transmits it to the base station 100. have. The master unit 200 and the hub unit 300 may be connected through an optical cable 600, and a plurality of hub units 300 may be connected to one master unit 200. The hub unit 300 may be directly connected to the master unit 200 or may be connected to another hub unit 300 in parallel.

The hub unit 300 is connected to one or more remote units 400 and may transmit an optical signal received from the master unit 200 to the remote unit 400. At this time, in the case of the in-building distributed antenna system, a remote unit is disposed so that a shadow area does not occur. For example, as shown in FIG. 1, remote units 400-1 to 400-n are disposed for each floor to improve communication coverage. Can be secured. In addition, the present invention is not limited thereto, and a plurality of remote units may be disposed on each floor, and one remote unit may be disposed on a plurality of floors.

The hub unit 300 and the remote unit 400 may be connected by a photoelectric composite cable 700. Optical signals are transmitted and received between the hub unit 300 and the remote unit 400 through the photoelectric composite cable 700, and power may be supplied from the hub unit 300 to the remote unit 400. This will be described later.

The communication signal transmitted to the master unit 200 is transmitted to the remote unit 400 through the hub unit 300, and the remote unit 400 communicates transmitted through one or more antennas 500-1 to 500-n. The signal can be transmitted to the user terminal.

Meanwhile, the wireless communication system may provide a service mode such as CDMA, WCDMA, or LTE, and the base station 100 may transmit a communication signal in a predetermined service mode. The master unit 200 may detect the type of communication signal received from the base station 100 and change an operation mode setting corresponding thereto.

Hereinafter, a detailed configuration of the master unit 200 and an automatic setting function of the operation mode will be described.

2 is a schematic diagram of a master unit of a distributed antenna system according to an embodiment of the present invention.

As shown in FIG. 2, the master unit 200 includes a signal input/output unit 210, an A/D converter 220, an FPGA unit, a communication method determination unit 240, a photoelectric conversion unit 260, and an optical transmission unit. 270 and a D/A converter 280 may be included. Further, the FPGA unit may include a signal detection unit 230 and a mode control unit 250 therein.

The signal input/output unit 210 provides an interface connected to the base station 100, and is connected to the base station 100 by wire to transmit and receive communication signals. Communication signals transmitted and received through the signal input/output unit 210 may be analog signals of RF signals. The downlink signal introduced from the base station 100 is converted into a digital signal by the A/D converter 220, and on the contrary, the uplink signal received from the user terminal is converted to an analog signal by the D/A converter 280. It may be transmitted to the base station 100 through the input/output unit 210.

The A/D converter 220 digitally converts the incoming signal received through the signal input/output unit 210 and samples it at predetermined intervals to generate a signal sample. The generated signal samples may be data in which a magnitude value of an incoming signal at a specific time is sequentially generated at predetermined time intervals, such as 00011 and 00100.

The generated signal sample may be used by the signal detector 230 as basic data for determining the presence or absence of a communication signal. Specifically, the signal detector 230 may determine whether the incoming signal is a meaningful communication signal by comparing the generated signal sample with a threshold value. To this end, the signal detection unit 230 may store and manage one or more threshold values set at a predetermined time interval in a separate table. If the data of the signal sample compared to the threshold value for a predetermined time exceeds the threshold value, the signal detector 230 may determine that the communication signal has been introduced.

Meanwhile, the signal detector 230 may determine whether a communication signal is received for each service frequency band. The wireless communication system provides wireless communication services using a certain frequency band, and the wireless communication system divides the allocated frequency band into one or more service frequency bands, and can allocate and use each service frequency band to a different communication service. have.

3 and 4 illustrate an example of such a service frequency band and an operation mode accordingly. In FIG. 3, the service frequency band usable in the wireless communication system is divided into four sub-frequency bands F0 to F3, and each sub-frequency band can be divided into a plurality of operation modes by a combination of services used. . For example, in the case of operation mode 5, the sub-frequency band F0 is not used, in F1, both the MAIN port and the MIMO port operate in LTE, and in F2 and F3, only the MAIN port operates in WCDMA.

4(a) shows a reception frequency pattern of a service frequency band in operation mode 5. When the frequency band usable in the wireless communication system is 1749.9 MHz to 1784.9 MHz, the sub frequency band F0 is not used, the signal received in the F1 frequency band is an LTE signal, and the WCDMA signal is transmitted through the F2 and F3 frequency bands. Can be received.

In this case, the master unit 200 determines the presence or absence of an incoming signal for each sub-frequency band and each communication method, and accordingly sets the operation mode to mode 5. Specifically, the signal detection unit 230 compares the size value of the signal sample of the incoming signal generated by the A/D converter 220 with a threshold value (for example, -50dBm) of a preset table, and flows in when it is above the threshold value. It can be determined that the signal is a communication signal including meaningful data. The mode controller 250 may reset the operation mode of the master unit 200 based on a determination result of the signal detection unit 230 as to the presence or absence of a communication signal.

At this time, if it is determined that the communication signal has not been received by the signal detection unit 230, the mode control unit 250 and the modules after it do not operate and operate in an idle mode, and are activated only when a communication signal is introduced. It can operate in an active mode.

The communication method determination unit 240 may analyze a packet of a communication signal introduced through a downlink to determine whether the corresponding signal is a WCDMA signal or an LTE signal. The determination of the communication method may be performed for each sub-frequency band, and the determination result may be transmitted to the mode controller 250.

The mode control unit 250 determines the communication method of each sub-frequency bandwidth based on the presence or absence of a communication signal acquired from the signal detection unit 230 and the communication method determination unit 240 and the communication method result of the received communication signal, and The operation mode of the master unit 200 can be set. Thereafter, the communication signal received from the base station may be transmitted to the UE through the hub unit 300 and the remote unit 400 on the downlink path in a set operation mode. The remote unit 400 controls the output frequencies from the MAIN antenna port and the MIMO antenna port according to the operation mode, and as shown in FIG. 4(b), in the case of mode 5, the MAIN antenna uses frequency bands F1, F2, and F3. And the MIMO antenna radiates the F1 frequency band.

In this case, the communication signal transmitted to the hub unit 300 and the remote unit 400 may be converted into an optical signal by the photoelectric conversion unit 260 and transmitted through the optical transmission unit 270.

Meanwhile, the communication signal received from the UE through the uplink path is received to the master unit 200 through the optical transmission unit 270, converted into a digital signal through the photoelectric conversion unit 260, and input to the FPGA unit. It may be converted into an analog signal in the D/A converter 280 for transmission to the base station.

Through this configuration, the master unit 200 can determine the presence or absence of a communication signal received from the base station 100 and a communication method, and automatically set an operation mode based on this, which is generated when the operation mode is manually set. Problems such as device failure and communication failure due to setting mistakes can be solved.

5 is a block diagram schematically showing a hub unit of a distributed antenna system according to an embodiment of the present invention.

Referring to FIG. 5, the hub unit 300 may include optical transmission units 310 and 340, photoelectric conversion units 320 and 330, a signal combining/distributing unit 360, and a power supply unit 350.

The optical signal transmitted from the master unit 200 may be received by the optical transmission unit 310 of the hub unit 300 and converted into an electric signal through the photoelectric conversion unit 320. The electric signal may be transmitted to the signal combining/distributing unit 360. The signal combiner/distribution unit 360 may distribute the signal transmitted from the photoelectric conversion unit 320 into a plurality of signals. That is, the hub unit 300 is connected to a plurality of remote units 400, and the signal combining/distributing unit 360 is configured to transmit signals to each of the remote units 400 connected to the hub unit 300. The signal can be distributed.

Each electric signal distributed by the signal combining/distributing unit 360 is transmitted to the photoelectric conversion unit 330 and converted into an optical signal, and the optical signal is transmitted to the photoelectric composite cable 700 by the optical transmission unit 340. It may be transmitted to the remote unit 400 through. The photoelectric conversion unit 330 and the optical transmission unit 340 may be disposed in the hub unit 300 as many as the number of remote units 400 connected to the hub unit 300.

The optical signal transmitted from the remote unit 400 is transmitted to the optical transmission unit 340 of the hub unit 300 through the photoelectric composite cable 700, and the photoelectric conversion unit 330, the signal combination/distribution unit 360, It may be transmitted to the master unit 200 through the photoelectric conversion unit 320 and the optical transmission unit 310.

The hub unit 300 may further include a power supply unit 350. The power supply unit 350 may supply power to the remote unit 400. That is, the remote unit 400 itself does not have a separate power supply source, and can be operated by power supplied from the power supply unit 350 of the hub unit 300. Power of the power supply unit 350 may be transmitted by a photoelectric composite cable 700 connecting the hub unit 300 and the remote unit 400. The photoelectric composite cable 700 is made of an optical fiber and a conductor wire, and transmits an optical signal between the hub unit 300 and the remote unit 400 through the optical fiber, and remotely from the hub unit 300 through the conductor wire. Power can be supplied to the unit 400. A detailed description of the photoelectric composite cable 700 will be described later.

A plurality of remote units 400 are connected to the hub unit 300, and all of the remote units 400 connected to the hub unit 300 may receive power from the hub unit 300. In this way, since there is no need to install a separate power supply for each of the plurality of hub units 300, installation of the remote unit 400 is easy, and the size of the remote unit 400 can also be reduced, so even in a narrow installation space. The remote unit 400 can be easily installed. In addition, since there is no power supply in the remote unit 400 itself, there is no need to install a UPS to maintain the power of the remote unit 400, and separate power work for installing the remote unit 400 is unnecessary. Can be saved. In addition, in the case of using the photoelectric composite cable 700 capable of transmitting 1200W or more, the network design of the distributed antenna system may be flexible by using a smaller number of remote units 400.

6 is a block diagram schematically showing a remote unit of a distributed antenna system according to an embodiment of the present invention.

6, the remote unit 400 includes an optical transmission unit 410, a photoelectric conversion unit 420, a digital signal processing unit 430, a D/A converter 440, an A/D converter 450, and a signal. An input/output unit 460 and an antenna 470 may be provided.

The optical signal transmitted through the photoelectric composite cable 700 is received by the optical transmission unit 410 of the remote unit 400, and the optical signal is converted into an electric signal through the photoelectric conversion unit 420, and the electric signal May be digitally processed by the digital signal processing unit 430 and converted into an analog signal by the D/A converter 440. The analog signal may be amplified by the signal input/output unit 460 and transmitted to the user terminal through the antenna 470.

The signal output from the user terminal is an antenna 470 of the remote unit 400, a signal input/output unit 460, an A/D converter 450, a digital signal processing unit 430, a photoelectric conversion unit 420, and an optical transmission unit. It may be transmitted to the hub unit 300 through the photoelectric composite cable 700 through 410.

As described above, the remote unit 400 is connected to the hub unit 300 through an optical fiber in the photoelectric composite cable 700, so that signals can be transmitted from the hub unit 300 spaced apart from a long distance without signal loss. I can. In the case of a conventional UTP cable (Unshielded twisted pair cable), the distance at which a signal can be transmitted within an allowable signal loss range is only a maximum of 100m, so there is a limitation in designing the system. However, according to an embodiment of the present invention, since a signal is transmitted through an optical fiber in the photoelectric composite cable 700, it is possible to transmit a signal over a long distance without signal loss, and accordingly, a flexible distributed antenna system design is possible.

In addition, since the remote unit 400 receives power from the hub unit 300 through the photoelectric composite cable 700 without a separate power supply device, installation cost can be saved in installing the remote unit 400, Since the remote unit 400 can be made relatively small, it can be installed in a relatively small installation space. Since power of 1200W or more can be supplied through the photoelectric composite cable 700, the remote unit 400 can transmit a high-power RF signal, so that an optimal network design is possible with a relatively small number of remote units 400. .

7 is a cross-sectional view schematically showing a photoelectric composite cable 700 of a distributed antenna system according to an embodiment of the present invention.

Referring to FIG. 7, the photoelectric composite cable 700 of the present invention includes an optical cable 20 disposed at the center of the photoelectric composite cable 700, and at least one first power line circumscribed to the optical cable 20. The unit 30 and at least one second power line unit 50 may be provided with an outer skin layer 70 surrounding and circumscribed to the first power line unit 30 and the second power line unit 50.

The outer skin layer 70 is a part forming the outer shape of the photoelectric composite cable 700, and may protect the optical cable and power line unit included in the photoelectric composite cable 700.

Preferably, the outer layer 70 has a circular shape of the first power line unit 30 and the second power line unit 50 so that the first power line unit 30 and the second power line unit 50 are inscribed at the same time. It may include a metal layer 71 that surrounds the shape and protects the power line units 30 and 50 and the optical cable 20 from external impacts, and an outer coating layer 73 surrounding the metal layer 71.

The metal layer 71 may be formed of a corrugated steel tape.

It is preferable that the outer coating layer 73 has flame retardant properties and is an eco-friendly resin. For example, the outer coating layer 73 may be made of polyethylene, polypropylene, or polyvinyl chloride (PVC).

The outer layer 70 is the first power line unit 30 so that the first power line unit 30 and the second power line unit 50 are inscribed at the same time instead of the metal layer 71 on the inner surface of the metal layer 71. And a waterproof tape 75 surrounding the second power line units 50 in a circular shape may be further provided. The waterproof tape 75 may be disposed in a form surrounding the power line units inside of a nonwoven fabric treated with a waterproof material. The waterproof coating layer 75 is formed in a way that a tape-shaped material is rolled horizontally or vertically. By providing such a waterproof tape, it is possible to prevent damage to optical fibers and cables due to moisture penetration.

In order to facilitate the peeling operation of the outer layer 70, the outer layer 70 (for example, the metal layer 71 or the waterproof tape 75) may be provided with a ripcord (not shown). .

The first power line unit 30 and the second power line unit 50 are one or more unit power lines 31; 51 composed of conductors and an insulating coating layer composed of an insulator surrounding the one or more unit power lines 31; 51 (33; 53) may be included. It is preferable that the power line units have a type conforming to the standard used for general electric power. The plurality of unit power lines 31 and 51 may be twisted with each other. The insulating coating layers 33 and 53 are painted in various colors depending on the intended use. The unit power lines 31 and 51 are preferably made of copper, and the insulating coating layers 33 and 53 are preferably made of a resin material containing polyethylene, polypropylene, or polyvinyl chloride.

The first power line unit 30 may correspond to a + terminal, and the second power line unit 50 may correspond to a-terminal. One first power line unit 30, one second power line unit 50, and one optical fiber unit (21 in FIG. 8) may be branched from the photoelectric composite cable 700 to form a set, The one set may be connected to one remote unit 500 to transmit signals and power.

8 is a schematic cross-sectional view of the optical cable shown in FIG. 7.

Referring to FIG. 8, the optical cable includes at least one optical fiber unit 21 having a predetermined number of optical fiber core wires 21a mounted in a plastic tube 21b made of a plastic resin, and a buffer tube 22 located at the center of the cable 20. It is gathered in the longitudinal direction around, and the sheath layer 24 has a structure surrounding the at least one optical fiber unit 21.

The plastic tube 21b constituting the optical fiber unit 21 is made of a plastic resin such as polypropylene (PP), polybutylene terephthalate (PBT), polycarbonate (PC), and polyamide (PA) such as nylon-12. It may be made, and preferably may be made of polybutylene terephthalate (PBT). The polybutylene terephthalate (PBT) resin has excellent flexibility and mechanical strength, and has a high crystallization rate, so that the degree of shrinkage in the longitudinal direction after the manufacture of the tube 21b is small.

The plastic tube 21b has a cylindrical shape as a whole, and has a through hole in which the optical fiber core wire 21a, a waterproofing material 21c, and the like can be mounted. Here, the outer diameter/inner diameter of the plastic tube 21b is determined by a standard according to the use of the cable 20, and the standard is the number of the optical fiber core wires 21a mounted inside the plastic tube 21b, It is determined according to the content of the waterproofing material 21c, the bending characteristics required by the cable 20, and the like.

That is, when the inner diameter of the plastic tube 21b is less than the standard, the content of the waterproofing material 21c included in the tube 21b is insufficient and the number of optical fiber cores 21a is also reduced, resulting in a decrease in data transmission efficiency that can be transmitted per unit time. On the other hand, when the outer diameter of the tube 21b exceeds the standard, the diameter of the cable 20 is unnecessarily increased, thereby reducing the flexibility of the cable 20, resulting in difficulty in winding.

In addition, the thickness of the plastic tube (21b) may be determined in consideration of the mechanical strength and flexibility required for the tube (21b), for example, the thickness of the tube (21b) is the outer diameter of the tube (21b) It may be at least 10%, preferably at least 15%.

Preferably, the plastic tube (21b) is formed by forming a color coating layer colored in different colors on the outside, it is easy to distinguish according to the function or function of each of the optical fiber unit (21), the optical fiber unit (21) when disconnecting It can be configured to facilitate the distinction of.

A predetermined number of the optical fiber core wires 21a are mounted in the plastic tube 21b forming the optical fiber unit 21. The number of optical fiber core wires 21a mounted in the plastic tube 21b may be 1, 2, or 3 or more as necessary. That is, the number of the optical fiber core wires 21a may vary depending on the transferable data transmission efficiency per unit time of the optical cable including the optical cable, flexibility of the cable, and the like.

Each of the optical fiber core wires 12 has a double cylindrical structure in which a portion called a cladding is wrapped around a portion called a core in the center, wherein the core is a silica having a high refractive index. By using glass fiber of a material, and the cladding is made of glass or synthetic resin made of silica, which has a relatively lower refractive index than the core, the light passing through the center occurs so that total reflection occurs to transmit a signal. Implement it to play a role. A core having a diameter of several µm is referred to as a single-mode optical fiber, and a core having a diameter of several µm is referred to as a multimode optical fiber, and is classified into a stepped type or a hill type optical fiber according to the refractive index distribution of the core.

In addition, the plastic tube 21b may be filled with a waterproofing material 21c such as a jelly compound, a waterproof powder, a waterproofing yarn, a combination thereof, together with the optical fiber core wire 21a. When moisture enters the optical cable 20, the mechanical reliability may decrease or hydrogen gas may be generated due to a chemical reaction with the metal in the cable 20, and moisture moves into the interior of the optical cable 20 and Corrosion of connecting equipment and terminating equipment may also occur.

Accordingly, the waterproofing material performs a function of preventing moisture from penetrating into the plastic tube 21b, and preferably ensures that the optical fiber core wire 21a flows in the plastic tube 21b.

As the waterproofing material 21c, the jelly compound may be made of a resin having excellent thermal stability, waterproofness, and electrical insulation, and preferably has high viscosity and excellent adhesion to the optical fiber core 21a and prevents moisture penetration. This could be an excellent thixotropic jelly compound.

In addition, as the waterproofing material 21c, the waterproofing powder is a super absorbent polymer (SAP), and has a property of absorbing water up to several tens to several hundred times its own weight, so that moisture penetrates into the plastic tube 21b. It is suitable for use as a waterproof application that prevents it from occurring. The waterproof powder may be a polyacrylic acid salt, a PVA maleic acid reactant, an isobutylene maleic acid copolymer, a polyacrylonitrile polymer, a polyethylene oxide crosslinked product, a starch acrylonitrile polymer, a starch acrylic acid graft polymer, and the like.

And, as the waterproofing material (21c), the waterproofing yarn may be inserted into the through hole of the plastic tube (21b), and the waterproofing yarn attached to the continuous yarn or the waterproofing powder processed into a thread form continuously Waterproof yarn made by twisting or bonding with yarn can be used.

The waterproof yarn may have a thickness of 300 to 3,000 denier, a swelling capacity of 20 g/g or more in distilled water, and a tensile strength of 3 to 150 N. When the thickness of the waterproof yarn is less than 300 denier, it is difficult to work because too many waterproof yarns are required to achieve the waterproof performance, and it causes an increase in the cost of the cable. In addition, when the swelling ability of the waterproof yarn in distilled water is less than 20 g/g, it may be difficult to achieve the intended waterproof performance, and when the tensile strength is less than 3 N, in the process of entering into the plastic tube 21b or a cable Disconnection may occur due to tensile stress generated during bending of.

As described above, in the optical cable 20 according to the present invention, at least one optical fiber unit 21 in which a predetermined number of optical fiber core wires 21a, waterproofing material 21c, etc. are mounted in the plastic tube 21b. ) Is collected in the longitudinal direction around the buffer tube 22 located at the center of the cable 20. The number of the optical fiber units 21 may be different depending on the use of the cable, and preferably 6 in order to facilitate the optical cable 20 to maintain its cross section in a circular shape.

On the other hand, due to the bending of the cable 20 that occurs when the optical cable 20 is wound on a reel, drum, etc., the optical fiber core wire of the optical fiber unit 21 included in the cable 20 ( A stress is applied to 21a), which may cause disconnection of the optical fiber core wire 21a, deterioration of characteristics, and the like.

In order to solve such a problem, the strain of the cable 20 due to bending stress generated by the bending of the optical cable 20 is increased due to the twisted optical fiber unit 21 being unfolded. It can be compensated for by the length that becomes. That is, to compensate the strain (strain) of the cable 20 due to winding of the reel of the optical cable 20, a margin is given to the length of the optical fiber unit 21 and the optical fiber core wire 21a included therein. For this purpose, the optical fiber unit 21 may be assembled around the center buffer tube 22 by helical twist or SZ twist.

In this case, the optical fiber units 21 may maintain a twisted state at a predetermined pitch, the pitch of which the optical fiber unit 21 twisted at this pitch is unfolded by bending of the optical cable 20, and thus the cable In order to compensate for the strain of (20), it may be appropriately selected in consideration of the diameter and the bending radius of the optical cable 20.

On the other hand, the buffer tube 22 is a plastic tube 21b of the optical fiber unit 21 and the plastic tube 21b of the optical fiber unit 21 in contact with it by absorbing the impact by deforming the shape when an impact, a load, etc. is applied to the optical cable 20. It not only protects the optical fiber core wire 21a, but also performs a function of imparting a tensile strength to the cable 20.

The buffer tube 22 may be made of the same plastic resin as the plastic tube 21b, preferably a foamed plastic resin having a lower strength than the plastic tube 21b, for example, foamed polyethylene, foamed It may be made of polyvinyl chloride (PVC) or the like. When the strength of the buffer tube 22 is lower than that of the plastic tube 21b, when a load is applied in the lateral direction of the cable 20, the shape of the buffer tube 22 is deformed. It is easy to maintain the shape and protect the optical fiber core wire 21a mounted therein.

There is no particular limitation on the shape of the buffer tube 22 as long as it can stably support the one or more optical fiber units 21 collected around the buffer tube 22. Preferably, the buffer tube 22 has a circular cross section, and the circular diameter is the optical fiber unit 21 so that it can stably circumscribe all the optical fiber units 21 collected around the buffer tube 22. ) Can be appropriately selected according to the diameter.

In the optical cable 20 according to the present invention, a tensile strength line (external to the empty space in the sheath layer 24), preferably to the optical fiber unit 21, the buffer tube 22, or both 23) may additionally be included. Here, the tensile strength tension wire 23 performs a function of protecting the optical fiber core wire 21a inside the optical cable 20 by supplementing the tensile strength of the optical cable 20, and Kevlar aramid yarn, It can be made of fiber glass epoxy rod, fiber reinforced polyethylene (FRP), high strength fiber, galvanized steel wire, steel wire, etc.

The optical cable 20 according to the present invention may have a structure in which the sheath layer 24 surrounds the one or more optical fiber units 21 collected around the buffer tube 22 as a center. The thickness of the sheath layer 24 may be appropriately selected according to the use of the optical cable 20, specifically, the overall diameter of the optical cable, required flexibility, and bending characteristics.

Meanwhile, the optical cable 20 according to the present invention may further include a reinforcing layer 25, a waterproof layer 26, or all of them between the sheath layer 24 and the at least one optical fiber unit 21.

When the sheath layer 24 is formed directly outside the optical fiber unit 21, the entire outer surface of the optical cable 20 is formed unevenly, or the material of the sheath layer 24 is a plastic tube of the optical fiber unit 21 ( 21b) It may be adhered to the material, and this may not be desirable because it not only degrades the aesthetics of the cable 20, but also easily receives unnecessary impact and frictional resistance during winding. Therefore, by wrapping the outside of the optical fiber unit 21 with a reinforcing layer 25 formed by transverse winding a metal reinforcing tape such as aluminum foil outside the optical fiber unit 21 or formed of a transparent film made of synthetic resin, a nonwoven fabric, etc. The sheath layer 24 can be formed in a state in which a close appearance is formed.

In addition, a waterproof layer 26 may be formed outside, inside, or both of the reinforcing layer 25. The waterproof layer 26 may be formed by transversely winding a waterproof tape such as a paper-made swellable tape on the optical fiber unit 21 or the reinforcing layer 25, and penetrates through the damaged portion of the sheath layer 24. It can perform the function of suppressing the penetration of moisture into the optical cable 20, in particular, when the waterproof layer 26 is disposed outside the reinforcing layer 25, the fluorine resin constituting the sheath layer 24 and Can achieve close adhesion.

In the optical cable 20 according to the present invention, the empty space between the sheath layer 24 and the optical fiber unit 21 is a bedding body made of a waterproof material such as jelly compound, waterproof powder, and waterproof yarn. Can be filled. The waterproof material such as the jelly compound, waterproof powder, and waterproof yarn may be the same as or different from the waterproof material 21c filled in the plastic tube 21b described above.

9 is a cross-sectional view schematically illustrating a photoelectric composite cable according to another modification.

Referring to FIG. 9, in the photoelectric composite cable 800, an optical cable 20 ′ is disposed in the center of the photoelectric composite cable 800, and a plurality of first power line units 30 circumscribed to the optical cable 20 ′. And a plurality of second power line units 50 are disposed, and the first power line unit 30 and the second power line unit 50 are provided with a skin layer 70 circumscribed thereto. It is the same as 700, but there is a difference in the configuration of the optical cable 20'. That is, in the optical cable 20 ′, the buffer tube 22 may be disposed at the center of the optical cable 20 ′, and the optical fiber units 21 ′ may be disposed so as to circumscribe the buffer tube 22. In that the plastic tube 21b' constituting the optical fiber unit 21' is a tight buffer, the photoelectric composite cable 700 of FIG. 7 in which the plastic tube 21b is a loose tube is different.

10 is a cross-sectional view schematically illustrating a photoelectric composite cable according to another modification.

Referring to FIG. 10, the photoelectric composite cable 900 includes a first power line unit 30, a second power line unit 50, and a ground wire 40 circumscribed to each other, and an outer skin layer 70 surrounding and circumscribed thereto. And, an optical fiber unit 21" that is externally in contact with the power lines 30 and 50 or the ground line 40 and is inscribed with the outer layer 70. The optical fiber unit 21" is an optical fiber unit of FIG. 21) or may have the same configuration as the optical fiber unit 21 ′ of FIG. 9.

Such a photoelectric composite cable 900 is not separately branched, but at the same time, by directly connecting the hub unit 300 and each remote unit 400 to transmit and receive an optical signal between the hub unit 300 and the remote unit 400 Power may be supplied from the hub unit 300 to the remote unit 400.

The photoelectric composite cable used in the distributed antenna system according to an embodiment of the present invention is not limited to those shown in FIGS. 7 to 10, and any form may be used as long as a power line and an optical cable are combined.

11 is a flowchart schematically illustrating a communication signal relay method of a distributed antenna system according to an embodiment of the present invention.

First, the master unit 200 receives an incoming signal from the base station through the signal input/output unit 210, digitally converts it in the A/D converter 220, and extracts a signal sample (S100). The extracted signal sample is transferred to the FPGA unit, and the signal detection unit 230 of the FPGA unit compares the signal sample with a preset threshold value for each service frequency band (S102), and if the size of the signal sample is greater than or equal to the threshold value, the corresponding service frequency It is determined that the communication signal using the band has been received from the base station (S104), and if the size of the signal sample is less than the threshold value, it is determined that the communication signal using the corresponding service frequency band has not been received from the base station (S108). If a communication signal is received, the communication method determination unit 240 may determine a service method of the communication signal and provide the result to the mode control unit 250.

Thereafter, the mode control unit 250 determines the presence or absence of a communication signal for each service frequency band using the communication signal detection result of the signal detection unit 230, and accordingly sets an operation mode of the master unit 200 (S110). In this case, the operation mode may be set by reflecting the result of the communication method determination by the communication method determination unit 240. Thereafter, the received communication signal may be converted into an optical signal by the photoelectric conversion unit 260, and the optical signal may be transmitted in an operation mode set through the optical transmission unit 270 (S112 ).

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

100: base station 200: master unit
300: hub unit 400: remote unit

Claims (22)

A master unit capable of transmitting and receiving a communication signal with a base station;
A hub unit for receiving the communication signal processed by the master unit or transmitting a communication signal to the master unit;
A remote unit capable of transmitting and receiving a communication signal with the hub unit; And
A photoelectric composite cable connecting the hub unit and the remote unit to each other; And,
The remote unit receives power from the hub unit through the photoelectric composite cable,
The master unit digitally converts the incoming signal from the base station and samples it at regular intervals to generate a signal sample; A signal detector for determining that a communication signal has been received when the size of the signal sample for each service frequency band is equal to or greater than a preset reference value; And a mode controller configured to set an operation mode based on a result of determining whether to receive the communication signal and information in an operation mode table; and
The operation mode table includes information on a communication method for each service frequency band of the communication signal,
When the signal detection unit determines that the communication signal has been received, the mode control unit sets the operation mode according to a communication method for each service frequency band of the communication signal included in the information of the operation mode table, Distributed antenna system. The method of claim 1,
The remote unit is a distributed antenna system, characterized in that operating on the power supplied from the hub unit without separate power. The method of claim 1,
The hub unit is a distributed antenna system, characterized in that provided with a power supply that can supply power to the remote unit. The method of claim 1,
The remote unit receives an optical signal from the hub unit through the photoelectric composite cable, and converts the optical signal into an electric signal. The method of claim 1,
Distributed antenna system, characterized in that the communication signal is transmitted and received between the hub unit and the remote unit through the photoelectric composite cable. The method of claim 1,
The photoelectric composite cable,
An optical cable disposed at the center of the photoelectric composite cable;
At least one first power line unit and at least one second power line unit surrounding and enclosing the optical cable; And
An outer skin layer surrounding the first power line units and the second power line units; And,
The optical cable,
A buffer tube disposed at the center of the optical cable;
At least one optical fiber unit including a plastic tube assembled in a longitudinal direction around the buffer tube and an optical fiber core wire mounted in the plastic tube; And
A sheath layer surrounding the optical fiber unit; Including,
One of the first power line unit, one of the second power line unit, and one of the optical fiber units are branched and connected to one of the remote units. The method of claim 6,
The buffer tube is a distributed antenna system, characterized in that each circumscribed to the at least one optical fiber unit has a diameter to stably support the optical fiber unit. The method of claim 6,
The plastic tube is a distributed antenna system, characterized in that consisting of polypropylene (PP), polybutylene terephthalate (PBT), polycarbonate (PC), polyamide (PA), or a combination thereof. The method of claim 8,
The buffer tube is a distributed antenna system, characterized in that made of a foamed plastic resin having a lower strength than the plastic tube. The method of claim 6,
Distributed antenna system, characterized in that a waterproofing material including a jelly compound, a waterproof powder, a waterproofing yarn, or a combination thereof is mounted together with the optical fiber core wire in the plastic tube. The method of claim 6,
Distributed antenna system, characterized in that the power is supplied to the remote unit through the power line. The method of claim 6,
Distributed antenna system, characterized in that the communication signal is transmitted and received between the hub unit and the remote unit through the optical cable. The method of claim 1,
The photoelectric composite cable has a first power line unit, a second power line unit, and a ground line circumscribed to each other, an outer skin layer surrounding and circumscribed thereto, and the first power line unit or the second power line unit or a ground line, and the Distributed antenna system, characterized in that consisting of an optical fiber unit inscribed in the outer layer. delete The method of claim 1,
And a communication method determination unit for determining a communication method of the incoming signal. delete The method of claim 15,
And the communication method determining unit determines a communication method of the incoming signal for each service frequency band. delete The method of claim 1,
And the mode control unit operates only when the communication signal is received by the signal detection unit. The method of claim 1,
And a signal input/output unit connected to the base station by wire to transmit and receive the communication signal. The method of claim 1,
A photoelectric conversion unit for photoelectric conversion of the communication signal; And
And an optical transmission unit for transmitting the photoelectrically converted optical signal in the set operation mode. delete

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