KR101426339B1 - UTP Cable Scalable Remote Radio Head and In-Building Repeater System including the Remote Radio Head - Google Patents

Abstract

A remote base station apparatus and an in-building relay system having an in-house expandability are disclosed. A remote wireless base station apparatus according to an embodiment of the present invention includes: a CPRI / OBSAI signal processing unit connected to a base station control unit through a first wired line and transmitting / receiving information to / from the base station control unit through a first digital communication method; And a signal processor for converting a signal of the first digital communication system received from the CPRI / OBSAI signal processor into a signal of a second digital communication system without converting the analog signal into a signal of a second digital communication system, And a master UTP interface transceiver for converting a signal of the second digital communication system received from the distributor into a signal of the first digital communication system without performing an analog signal conversion process.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a remote base station apparatus and an in-building repeater system having an in-

More particularly, the present invention relates to a signal transmission between a base station control unit and a remote base station apparatus installed in a building in a distributed base station system, a signal transmission between the remote base station apparatus and a distributed apparatus installed in a plurality of shaded areas in a building, To-digital signal transmission without analog signal conversion.

A mobile communication service system generally comprises a base station, a base station controller, an exchange, and a terminal station. A base station and a terminal station communicate with each other in a constant frequency band, and each base station has a certain radius of a call. Accordingly, a plurality of base stations are appropriately arranged, and the call radius of each base station is overlapped with each other, thereby widening a callable area. However, even if the entirety of the city is covered by the arrangement of the plurality of base stations, a call shaded area that can not be talked is generated in a book district, a large building underground space, and a high-rise building. One of the ways to solve this problem and expand the area is the installation of the relay system. Such a relay system is classified into an optical relay system, an RF relay system, a microwave relay system, and an in-building relay system depending on the application area and relay method. An optical repeater system is used in an urban area or a suburban area, and a microwave transmission system is used when the visibility is several Km, and an in-building transit system can be used in an apartment complex, a large building, and an underground parking lot.

The conventional building relay system includes a master device installed on a base station, a roof of a building or the like and connected to the base station by wireless or wire, a plurality of distribution devices connected to the master device by wire, . ≪ / RTI >

 The base station and the master device transmit and receive RF signals (analog signals) wirelessly or wired, and the master device and the plurality of distributed devices transmit and receive digital signals.

As a result, the RF signal (analog signal) transmitted from the base station is distorted due to noise or the like in the process of being transmitted to the master device, and the RF signal whose quality is deteriorated is received by the master device, Since the degraded RF signal is converted into a digital signal and transmitted to the plurality of dispersing apparatuses, a signal distorted due to noise or the like is received in the plurality of dispersing apparatuses. As a result, There is a problem that a low-quality signal is received at the terminals located thereon, so that there occurs a problem that the quality of a call is deteriorated.

In a distributed base station system, signal transmission between a base station control unit and a remote base station device installed in a building and signal transmission between a remote base station device and a distributed device installed in a plurality of shaded areas in a building are all digital And a high-quality signal is transmitted to a plurality of dispersing apparatuses, has been proposed.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems that are not mentioned can be clearly understood by those skilled in the art from the following description.

An in-building relay system according to an aspect of the present invention includes a base station control unit, a remote wireless base station device connected to a first wired connection with the base station control unit and a remote wireless base station device installed in a building, Wherein the remote base station apparatus transmits and receives information through the first wired line and the base station control unit through a first digital communication method, Wherein the first digital communication method and the second digital communication method perform signal conversion between the first digital communication method and the second digital communication method without performing an analog signal conversion process, A signal of the second digital communication system, and a signal of the second digital communication system, And translating the same communication signal.

The first wired line may be an optical cable.

The second wire may be an unshielded twisted pair (UTP) cable.

The first digital communication method may be a Public Public Radio Interface (CPRI) or an Open Base Station Architecture Initiative (OBSAI) communication method.

The second digital communication method may be a Gigabit Ethernet communication method.

The remote wireless base station apparatus may include an AC power supply / DC power conversion apparatus that provides a DC power required for operation of the plurality of dispersing apparatuses in a Power Over Ethernet (POE) manner.

The plurality of distributing apparatuses may include a DC power supply / DC power supply converting apparatus that converts DC power supplied by the Ethernet power supply method into DC power required for operation of an internal constituent circuit.

According to another aspect of the present invention, there is provided a remote wireless base station apparatus comprising: a CPRI / OBSAI signal processing unit connected to a base station control unit through a first wired line and transmitting / receiving information to / from the base station control unit through a first digital communication method; And a signal processor for converting a signal of the first digital communication system received from the CPRI / OBSAI signal processor into a signal of a second digital communication system without converting the analog signal into a signal of a second digital communication system, And a master UTP interface transceiver for converting a signal of the second digital communication system received from the distributor into a signal of the first digital communication system without performing an analog signal conversion process.

The remote wireless base station apparatus may further include an AC power supply / DC power conversion apparatus for providing a DC power required for operation of the plurality of dispersing apparatuses in a Power Over Ethernet (POE) manner.

The remote wireless base station apparatus includes a wireless base station controller for transmitting a signal transmitted from the base station controller to an inside or outside of a building or receiving signals from a plurality of terminals located inside or outside the building and transmitting the signal to the base station controller through the CPRI / And an output unit.

According to the remote base station apparatus and the in-building relay system having the intra-city scalability according to the embodiment of the present invention, signal transmission between the base station control unit and the remote base station apparatus installed in the building, The signal transmission between the distributed devices installed in the building is performed in a digital manner without going through the analog signal conversion process, so that the shaded area for mobile communication occurring in a large building, apartment house, or commercial building can be easily solved.

In addition, since a signal from the base station control unit is transmitted to a plurality of distributed devices located in the shadow area through the remote wireless base station device, the signals are not affected by noise, and so a high quality signal can be transmitted to a plurality of distributed devices located in the shadow area.

In order to solve the difficulties of wiring installation inside the existing building, by applying the Ethernet power supply (POE) technology which utilizes the UTP cable fully and transmits the digital signal and the UTP cable at the same time without the power wiring, It is possible to reduce the construction cost of the network of the operator, and to make efficient operation and maintenance possible.

FIG. 1 is a diagram illustrating a configuration of an in-building relay system according to an embodiment of the present invention.
2 is a detailed block diagram of the remote wireless base station apparatus shown in FIG.
3 is a detailed block diagram of the master UTP interface transceiver shown in FIG.
FIG. 4 is a view showing a detailed configuration of the dispersing apparatus shown in FIG. 1. FIG.
5 is a detailed block diagram of the distributed UTP interface transceiver shown in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

FIG. 1 is a diagram illustrating a configuration of an in-building relay system according to an embodiment of the present invention.

1, the in-building relay system according to the present invention includes a base station control unit 1, a remote wireless base station device 2 connected to a first wired connection with a base station control unit 1, And a plurality of dispersing devices (3) connected to the first wired line (2) and the second wired line, respectively installed in one of the plurality of shaded areas of the building. Further, when the number of the plurality of the dispersing devices 3 exceeds the number of ports provided by the remote base station apparatus 2 or when the maximum transmission distance of signals transmitted to the distributed apparatus by the remote base station apparatus 2 is It is possible to further include a hub extension unit 4 for increasing the number of hubs.

The remote wireless base station apparatus 2 transmits and receives information via the first wired line to the base station control section 1 in a first digital communication manner and transmits a plurality of distributed apparatuses 3 The first digital communication method and the second digital communication method through the second wired line connected to the second digital communication method without performing an analog signal conversion process.

The dispersing device 3 converts a signal of the second digital communication system and a mobile communication signal transmitted to or from the shadow area. At this time, the first wired line may be an optical cable, and any transmission medium that can transmit and receive information between the base station control unit 1 and the remote wireless base station apparatus 2 by the first digital communication method may be used have. The second wired line may be an unshielded twisted pair (UTP) cable. If the second wired line is a transmission medium capable of transmitting and receiving information between the remote base station apparatus 2 and the plurality of distributed apparatuses 3 by the second digital communication method, It is also acceptable. Also, the first digital communication method may be a Public Public Radio Interface (CPRI) or an Open Base Station Architecture Initiative (OBSAI) communication method. That is, the base station control unit 1 and the remote wireless base station apparatus 2 can transmit and receive information using the CPRI communication method or the OBSAI communication method. Meanwhile, the second digital communication method may be a Gigabit Ethernet communication method. That is, the remote base station apparatus 2 and a plurality of distributed apparatuses (including a plurality of distributed apparatuses connected through the hub extension unit 4) 3 can transmit and receive information through the Gigabit Ethernet communication method. Accordingly, the base station control unit 1 and the remote base station apparatus 2 transmit and receive a digital signal, not an analog signal, through the optical cable, and the remote base station apparatus 2 and the plurality of distributed apparatuses 3 also perform an analog signal conversion process The signal transmitted from the base station control unit 1 to the plurality of distributed apparatuses through the remote wireless base station apparatus 2 can be transmitted with a high quality signal unaffected by noise or the like have.

The remote wireless base station apparatus 2 may be provided with an AC power supply / DC power supply apparatus for providing a DC power required for operation of the plurality of dispersing apparatuses 3 by a power over Ethernet (POE) scheme . The AC power supply / DC power supply conversion apparatus will be described later.

In response to this, the plurality of dispersing devices 3 may include a DC power supply / DC power supply converting device for converting DC power supplied by the Ethernet power supply method into DC power required for operation of an internal constituent circuit. The DC power supply / DC power supply conversion apparatus will be described later. Since the plurality of dispersing devices 3 operate the internal constituent circuit by using the DC power provided by the Ethernet power supply method, a separate AC power supply / DC power supply conversion device is not required and the construction of the power supply facility can be omitted have.

2 is a detailed block diagram of the remote wireless base station apparatus shown in FIG.

2, the remote wireless base station apparatus 2 includes a CPRI / OBSAI signal processing unit 10, an indoor / outdoor wireless output unit 11, a master UTP interface transceiver 19, an AC / DC power converter 20, And a prosumer 21.

The CPRI / OBSAI signal processing unit 10 is connected to the base station control unit 1 through an optical cable in a first wired and exemplary embodiment and communicates with the base station control unit 1 through a first digital communication system, ) Or OBSAI communication method.

The indoor / outdoor radio output unit 11 includes a digital / analog conversion unit 12, an up converter 13, a high output amplifier 14, a transmission / reception filter 15, a low noise amplifier 16, a down converter 17, OBSAI signal processing unit 10 and receives the signals from a plurality of terminals (not shown) located inside and outside the building, and transmits the signals to the CPRI / OBSAI signal processing unit 10 To the base station control unit 1. [

The analog-to-digital converter 12 converts the signal of the first digital communication system into an analog signal. The up converter 13 converts the analog signal converted by the digital-analog converter 12 into a frequency band of a mobile communication signal The high power amplifier 14 amplifies the analog signal outputted from the up converter 13 and the transmission and reception filter 15 amplifies the analog signal amplified by the high power amplifier 14 by using the antenna ANT The low noise amplifier 16 amplifies the weak mobile communication signal received from the terminal through the antenna ANT in a low noise manner and the down converter 17 amplifies the mobile communication signal amplified by the low noise amplifier 16, And the analog / digital converter 18 converts the mobile communication signal output from the falling converter 17 into a digital signal.

The master UTP interface transceiver 19 converts a signal of the first digital communication system received from the CPRI / OBSAI signal processor 10 into a signal of a second digital communication system without performing an analog signal conversion process, Converts the signal of the second digital communication system received from the dispersing device 3 of the first digital communication system into a signal of the first digital communication system without performing an analog signal conversion process. In this case, the signal of the first digital communication system may be a CPRI communication system signal or an OBSAI communication system signal, and the signal of the second digital communication system may be a Gigabit Ethernet signal. At this time, the master UTP interface transceiver 19 may be integrated with the CPRI / OBSAI signal processing unit 10 and one board, or may be implemented on a separate substrate.

The AC power supply / DC power converter 20 converts the AC power to DC power to supply the DC power required for operation of the plurality of dispersing devices 3 connected to the remote base station apparatus 2 by the UTP cable, To the UTP interface transceiver 19. The master UTP interface transceiver 19 provides the DC power applied from the AC power supply / DC power converter 20 to the plurality of the dispersing apparatuses 3 by the power over Ethernet (POE) method.

The processor unit 21 controls the operation of the up-converter 13, the high-power amplifier 14, and the down-converter 17.

3 is a detailed block diagram of the master UTP interface transceiver shown in FIG.

3, the master UTP interface transceiver 19 includes a digital-to-digital converter 191, a gigabit physical layer converter 192, and an Ethernet power supply 193.

The digital-to-digital conversion unit 191 is connected to the CPRI / OBSAI signal processing unit 10 through an internal wire, and transmits signals of one serial first digital communication system to a parallel digital communication system of n (natural number) Digital converter 191 converts a signal of one first digital communication system, a signal of a CPRI communication system, or a signal of an OBSAI system, for example, to a parallel UTP digital signal and performs inverse conversion thereof. It is possible to convert the signal of the communication system into a 4-pair parallel UTP digital signal. This is merely an example and may be changed depending on the situation of the system.

The gigabit physical layer converter 192 converts the UTP digital signal converted by the digital-to-digital converter 191 into a Gigabit Ethernet signal so as to be transmitted through a UTP cable, and performs inverse conversion thereof. In one embodiment, up to eight distributed devices can be connected to one remote base station device by applying two commercially available 1: 4 schemes for the Internet in which digital signals can be transmitted and received using a UTP cable.

The Ethernet power supply 193 supplies the DC power applied from the AC power supply / DC power converter 20 to the plurality of dispersing devices 3 via the UTP cable in the Ethernet power supply mode (POE).

FIG. 4 is a view showing a detailed configuration of the dispersing apparatus shown in FIG. 1. FIG.

4, the dispersing apparatus 3 includes a distributed UTP interface transceiver 3, a digital / analog converter 31, a dispersive up converter 32, a high power amplifier 33, a distributed transmission / reception filter 34, An analog-to-digital converter 37, a DC power supply / DC power converter 38, and a distributed processor 39. The amplifier 35,

The distributed UTP interface transceiver 30 transmits and receives signals of the second digital communication system through the UTP cable to the remote wireless base station apparatus 2. [

The digital / analog converter 31 converts the signal of the second digital communication system received by the distributed UTP interface transceiver 30 into an analog signal having an intermediate frequency band.

The dispersion rise converter 32 raises the analog signal having the intermediate frequency band to the frequency band of the mobile communication signal.

The high-power amplifier 33 amplifies the analog signal raised to the frequency band of the mobile communication signal.

The distributed transmission / reception filter 34 emits the analog signal amplified by the high-power amplifier 33 to the space in the shadow area through the antenna ANT.

The low noise amplifier 35 low-noise amplifies the weak mobile communication signal received through the antenna ANT connected to the distributed transmission / reception filter 34 from the terminal located in the shadow area.

The dispersion-down converter 36 down-converts the low noise amplified mobile communication signal from the low noise amplifier 36 to an intermediate frequency band.

The analog / digital converter 37 converts the mobile communication signal converted by the dispersion-down converter 36 into a digital signal, that is, a signal of the second digital communication system. The thus converted signal of the second digital communication system can be transmitted to the remote wireless base station apparatus 2 through the distributed UTP interface transceiver 30.

The DC power supply / DC power converter 38 converts the DC power supplied via the distributed UTP interface transceiver 30 into the DC power supplied by the Ethernet power supply method to the DC power required for operation of the internal constituent circuit of the dispersing device 3. Accordingly, in order to obtain the DC power required for the operation of the internal constituent circuit, the dispersing device 3 does not need to have a separate AC power source / DC power source converter, thereby omitting the construction of the power source facility.

The distributed processor unit 39 controls the operation of the distributed up-converter 32, the high-output amplifier 33, and the distributed fall-down converter 36. [

5 is a detailed block diagram of the distributed UTP interface transceiver shown in FIG.

5, the distributed UTP interface transceiver 30 includes an Ethernet power supply 300, a Gigabit physical layer converter 301, and a Gigabit Ethernet signal processing unit 302. [

The Ethernet power supply 300 applies the DC power supplied from the remote wireless base station apparatus 2 via the UTP cable in the Ethernet power supply mode (POE) to the DC power / DC power converter 38.

The gigabit physical layer converter 301 converts the signal of the second digital communication system received from the remote wireless base station apparatus 2 through the UTP cable, for example, the Gigabit Ethernet signal into the UTP digital signal, and also performs the inverse conversion thereof.

The gigabit Ethernet signal processing unit 302 converts the parallel digital signals of n (natural numbers) pairs to serial, and also performs inverse conversion thereof. In one embodiment, four pairs of parallel UTP digital signals are converted to serial and reverse inverse thereof.

The present invention has been described above with reference to the embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. Therefore, the scope of the present invention is not limited to the above-described embodiments, but should be construed to include various embodiments within the scope of the claims and equivalents thereof.

Claims (14)

A remote base station apparatus connected to the base station control unit through a first wired connection and installed in a building, and a plurality of distributed wireless base stations connected to a second wired connection with the remote base station apparatus and installed in one of a plurality of shaded areas of the building, An in-building repeater system including an apparatus,
The remote base station apparatus transmits and receives information through the first wired line and the first wired line in a first digital communication method and transmits and receives information through the second wired line connected to the plurality of distributed apparatuses through a second digital communication method, And performing signal conversion between the first digital communication method and the second digital communication method without performing an analog signal conversion process,
Wherein the dispersing device converts a signal of the second digital communication system and a mobile communication signal transmitted to the shade area or received from the shade area,
The first digital communication method is a Public Public Radio Interface (CPRI) or Open Base Station Architecture Initiative (OBSAI)
The second digital communication method is a Gigabit Ethernet communication method,
The remote wireless base station apparatus includes an AC power source / DC power source conversion device for providing a DC power required for operation of the plurality of dispersing devices in a Power Over Ethernet (POE)
Wherein the plurality of distributing apparatuses include a DC power supply / DC power supply converting apparatus for converting DC power supplied by the Ethernet power supply method into DC power required for operation of an internal constituent circuit. The method according to claim 1,
And the first wired line is an optical cable. The method according to claim 1,
And the second wired line is an unshielded twisted pair (UTP) cable. delete delete delete delete A CPRI / OBSAI signal processing unit connected to the base station control unit through a first wired line and transmitting / receiving information to / from the base station control unit through a first digital communication method;
The signal of the first digital communication system received from the CPRI / OBSAI signal processing unit is converted into a signal of the second digital communication system without performing an analog signal conversion process, and a plurality of dispersions A master UTP interface transceiver for converting a signal of a second digital communication scheme received from the device into a signal of a first digital communication scheme without performing an analog signal conversion process; And
And an AC power supply / DC power conversion apparatus for providing a DC power required for operation of the plurality of dispersing apparatuses in a power over Ethernet (POE) manner,
The first digital communication method is a Public Public Radio Interface (CPRI) or Open Base Station Architecture Initiative (OBSAI)
Wherein the second digital communication method is a Gigabit Ethernet communication method. The method of claim 8,
Wherein the first wire is an optical cable. The method of claim 8,
And the second wired line is an unshielded twisted pair (UTP) cable. delete delete delete The method of claim 8,
Wherein the remote wireless base station apparatus comprises:
And an indoor / outdoor wireless output unit for transmitting a signal transmitted from the base station controller to the inside / outside of the building or receiving signals from a plurality of terminals located inside / outside the building and transmitting the signal to the base station controller through the CPRI / OBSAI signal processor To the remote base station apparatus.

Images