KR20090096786A - An in-building mobile communication relay system with multi-interface - Google Patents

Abstract

A building inside mobile radio communications relay system having a multiplex interface is provided to use a link system between 'apparatuses sending and receive the mobile communications signal in the building inside by equipping UTP(untwisted paired) and optical cable interface. An IMS(In-building Master System)(202) converts the digital light or the radio frequency signal received from a base station or an RF(Radio Frequency) relay into the digital signal. The inputted digital signal is converted into the digital light or the radio frequency signal and transmits to the base station or the RF relay. An IRTS(In-building Remote Terminal System)(206) outputs the RF signal which is transmitted from the mobile communication terminal and outputs the digital signal through a wireless antenna. An IHS(In-building Hub System)(204) relays the digital signal between IMS and IRTS.

Description

In-building mobile communication relay system with multiple interfaces {AN IN-BUILDING MOBILE COMMUNICATION RELAY SYSTEM WITH MULTI-INTERFACE}

The present invention relates to a mobile communication relay system in a building having multiple interfaces, and more particularly, a method of connecting a hub system or a terminal system installed inside a building to selectively use a UTP cable and an optical cable as needed. The present invention relates to a mobile communication relay system in a building having multiple interfaces.

In general, radio waves emitted from base stations of mobile communication systems are difficult to reach inside large buildings, behind hills, hills, tunnels, subways, and the like, and these areas are likely to be unstable for mobile communication. Therefore, shadowed areas exist due to problems such as the location and the topography of the base station.

As a solution for eliminating the shadow area, a repeater that can cover the shadow area that can not be called with low prices and weak radio waves is used. In particular, in-building RF repeaters are widely used as devices for eliminating shadow areas in buildings.

1 is a block diagram showing a connection state of an in-building relay system according to the prior art, which schematically shows a connection state of an apparatus for distributing a mobile communication signal transmitted from a base station 1.

The building 10 is installed with an IMS (In-Building Master System) 11 that is connected to the base station 1 and wired or wireless to exchange mobile communication signals. In addition to the base station 1, the IMS 11 is also connected to the RF repeater 15 installed on the roof of the building 10 to exchange signals.

The IMS 11 converts a mobile communication signal (RF signal) introduced into the building into a digital signal and transmits the digital communication signal to an In-Building Hub System (IHS) 12 installed in an appropriate number according to the building height.

The number of IHS 12 will vary depending on the height of the building, but typically one or more IHS 12 per floor is installed.

The IHS 12 transmits the input digital communication signal to an IRTS (In-Building Remote Terminal System) 13 installed in various places of the building, and the IRTS 13 converts the digital communication signal into an RF signal and transmits it through a wireless antenna. . The mobile communication terminal located inside the building can provide a mobile communication service to the user while exchanging RF signals with the IRTS 13 located in the nearest location.

However, conventionally, when connecting each component (IMS, IHS, IRTS, etc.) inside the building, UTP (Unshielded Twisted Pair) cable 14, which is mainly used in general telephone lines or LANs, was used. .

When connecting the relay devices using the UTP cable 14, there is an advantage that the gigabit transmission of the communication signal is possible, but due to the nature of the UTP transmission method can be connected to a place 100m or more away from the IMS (11) Was not. Therefore, when the height of the building is high, it is necessary to install a large number of IHS (12) to reduce the distance from the IMS (11), which was expensive and inconvenient to install.

The present invention for solving the above problems is provided with both a UTP cable connection interface and an optical cable connection interface in order to be able to use the connection method between the device for transmitting and receiving mobile communication signals in the building from among UTP cable and optical cable. An object of the present invention is to provide a mobile communication relay system in a building having multiple interfaces.

To this end, by providing an Ethernet converter and a CWDM converter at the same time in the relay device constituting the mobile communication relay system, to provide a mobile communication relay system in the building having a multi-interface to selectively apply the communication method according to the building situation The purpose.

The present invention for solving the above problems is a system for relaying a mobile communication signal in a building, which is installed inside the building and converts a digital optical signal or an RF signal received from a base station or an RF repeater into a digital communication signal or outputs An IMS converting the input digital communication signal into a digital optical signal or an RF signal and transmitting the digital communication signal to the base station or the RF repeater; An IRTS for converting and outputting an RF signal transmitted from a mobile communication terminal located in a building into a digital communication signal, or for converting an input digital communication signal into an RF signal and outputting the RF signal through a wireless antenna; An IHS connected between the IMS and the IRTS to relay a digital communication signal, wherein the IMS, IHS, and IRTS include both a UTP cable connection interface and an optical cable connection interface, and either UTP cable or optical cable. It is characterized in that for selectively using the transmission and reception of the communication signal.

It is connected between the IHS and the IRTS and relays a digital communication signal, and converts an RF signal transmitted from a mobile communication terminal located in a building into a digital communication signal and outputs the digital communication signal to the IHS, or a digital communication signal input from the IHS. IRIS to convert to an RF signal and output through a wireless antenna; wherein the IRIS comprises both a UTP cable connection interface and an optical cable connection interface, characterized in that for transmitting and receiving.

The IMS, the IRTS, the IRIS, and the IHS include an FPGA converting an input digital communication signal into a gigabit transmission format; An Ethernet converter converting a communication signal of a gigabit transmission format output from the FPGA into an Ethernet transmission format and outputting the same through a UTP cable; And a CWDM conversion unit converting a communication signal of a gigabit transmission format output from the FPGA into an optical communication transmission format of CWDM and outputting the same through an optical cable. The FPGA may include any one of the UTP cable and the optical cable. The Ethernet converter and the CWDM converter is selectively controlled to transmit a communication signal through one.

The IHS includes an FPGA; An Ethernet converter converting a communication signal of a gigabit transmission format output from the FPGA into an Ethernet transmission format and outputting the same through a UTP cable; And a CWDM conversion unit converting a communication signal of a gigabit transmission format output from the FPGA into an optical communication transmission format of a CWDM type and outputting the optical signal through an optical cable. The FPGA may be input in an Ethernet transmission format or an optical communication transmission format. Output digital communication signal without change of transmission format, or convert digital communication signal of Ethernet transmission format into digital communication signal of optical communication transmission format, and convert digital communication signal of optical communication transmission format into digital communication signal of Ethernet transmission format. The Ethernet converter and the CWDM converter to selectively control so as to.

The base station or RF repeater is characterized in that for transmitting and receiving RF signals used in 2G, 3G, WiMAX mobile communication network.

According to the present invention, in the method of connecting the relay devices in the building to each other, it is possible to use both UTP cable or optical cable has the effect that it is possible to build a relay system in the building cheaply and easily.

Hereinafter, a mobile communication relay system (hereinafter, referred to as a relay system) in a building having multiple interfaces will be described with reference to the drawings.

2 is a block diagram illustrating a connection state of a mobile communication relay system inside a building according to an exemplary embodiment of the present invention.

As shown in FIG. 2, the relay system 200 of the present invention is connected to the base station 100 or the RF repeater 110.

Base station 100 is a system that is connected to the mobile phone and the wireless section to control the mobile phone and connect the call channel. As the mobile communication network, 2G (second generation) of the CDMA system, 3G of the WCDMA system, and WiMAX (WIBRO) system, which is called 3.5 generation, are used.

The base station 100 includes base station modules 102, 104, and 106 that can form a communication channel with a mobile communication terminal according to each communication method. The base station modules 102, 104, and 106 are connected to the MHU (Master Hub Unit) 108 through the RF interface.

The MHU 108 converts the RF mobile communication signal transmitted from the base station 100 into a digital signal and transmits it to the relay system 200 installed in the building, which is typically transmitted by three base station modules 102, 104, and 106. Only two of the RF signals are selected and transmitted.

In addition, when it is difficult to directly connect to the base station 100 according to the location or shape of the building it may be connected to the mobile communication network wirelessly through the RF repeater 110 installed on the top floor of the building.

Since the method of accessing the mobile communication network through the base station 100 or the RF repeater 110 and connecting a call with the mobile communication terminal is the same as that of the related art, a detailed description thereof will be omitted. Only the connection relationship of each component which comprises this invention is demonstrated.

The mobile communication signal (digital optical signal, RF signal) transmitted from the base station 100 or the RF repeater 110 is input to the IMS 202 installed in the building.

The IMS 202 is installed in a communication room inside a building, and converts a digital optical signal or an RF signal received from the base station 100 or the RF repeater 110 into a digital communication signal, or outputs the digital communication signal. The device converts an optical signal or an RF signal and transmits the same to the base station 100 or the RF repeater 110.

To this end, the IMS 202 is provided with an RF signal amplifying converter and a digital signal converter.

3 is a block diagram showing an internal configuration of an IMS.

As shown in FIG. 3, the analog RF signal transmitted through the RF repeater 110 is input to the IMS 202 through the multiplexer 202a, and the input RF signal is an IMFCU (intermediate frequency conversion module) 202b. Signal is amplified and converted to intermediate frequency.

It is preferable that the IMFCU 202b is provided separately with a module for processing communication standard signals of 2G, 3G, and Wimax.

The RF signal converted to the intermediate frequency is converted into a digital communication signal by an ADC (Analog / Digital Converter) 202c, and then converted into a Giga-bit transmission format by a Field Programmable Gate Array (FPGA).

The FPGA 202e is a device that converts a digital communication signal into a frame form to enable gigabit transmission. In contrast, the FPGA 202e reframes a communication signal of a gigabit transmission format and converts it into an analog RF signal.

On the other hand, the mobile communication signal input from the MHU 108 through the optical communication method is directly input to the FPGA (202e) without additional processing is converted into a gigabit transmission format, this configuration can be selectively employed.

The digital communication signal converted into the gigabit transmission format by the FPGA 202e is transmitted to the IHS 204 installed at a predetermined position inside the building.

Conventionally, only one UTP cable connection interface or optical cable connection interface is provided as an interface for connecting the IMS 202 and the IHS 204, and thus cannot be converted to other methods. However, in the present invention, both interfaces are provided in the IMS 202 so that the connection method can be switched according to the user's selection.

That is, both the UTP cable connection interface and the optical cable connection interface are installed in eight ports formed in the FPGA 202e, and one method is selected under the control of the FPGA 202e to output a communication signal.

Which of the two types of interfaces is used is automatically recognized by the FPGA 202e or determined by an embedded program.

The UTP cable connection interface includes an Ethernet converter 202f for converting a communication signal of a gigabit transmission format output from the FPGA 202e into an Ethernet transmission format and outputting the UTP cable.

In addition, the optical cable connection interface includes a CWDM conversion unit 202g for converting a communication signal of a gigabit transmission format output from the FPGA 202e into an optical communication transmission format of a CWDM (Coarse Wavelength Division Multiplexing) method and outputting the same through an optical cable. do.

When the FPGA 202e transmits a communication signal of a gigabit transmission format to one of the two types of converters 202f and 202g, the selected converters 202f and 202g convert the format and transmit the format through a UTP cable or an optical cable. The communication signal is transmitted to the IHS 204, the In-Building Remote Terminal System (IRTS), and the In-Building Remote Intermediate System (IRS).

The IRIS 208 performs a function of transmitting a communication signal to an IRTS 206 connected to an end, such as the IHS 204, and a function of exchanging an RF signal with a mobile communication terminal, such as an IRTS 206. to be. That is, the IRIS 208 can simultaneously perform the function as the intermediate hub and the end radio access terminal.

On the other hand, Ethernet or optical communication signals transmitted from the IHS 204, the IRTS 206, and the IRIS 208 are also converted into the gigabit transmission format by either the Ethernet converter 202f or the CWDM converter 202g. It will then be input to the FPGA 202e. The digital communication signal input to the FPGA 202e is converted into an analog RF signal by the DAC (Digital / Analog Converter) 202d and is sent to the RF repeater 110.

The power supply unit (IPSU) 202h supplies power of -48V to the Ethernet conversion unit 202f by a PoE (Power over Ethernet) transmission method when the IRTS 206 and the IRIS 208 are interlocked.

Meanwhile, the communication signal input from the MHU 108 through the optical cable may be configured to be directly input to the FPGA 202e through the SerDes interface 202l.

Like the IMS 202, the IHS 204, the IRTS 206, and the IRIS 208 are all provided with interfaces for connecting the UTP cable and the optical cable, respectively. Even in this case, the Ethernet converter and CWDM converter are installed at the same time in the FPGA included in each component so that both communication methods can be used.

When the communication signal is output from the IMS 202 through the optical cable and transmitted to the IHS 204, the IHS 204 does not necessarily have to output the communication signal through the optical cable. The communication signal suitable for the connection method of the IRIS 208 may be output.

Therefore, it is possible to operate the normal relay system without changing the connection cable of the equipment installed in the building.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the above-described technical configuration of the present invention may be embodied by those skilled in the art to which the present invention pertains without changing its technical spirit or essential features of the present invention. It will be appreciated that the present invention may be practiced as. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

1 is a block diagram showing a connection state of the in-building relay system according to the prior art.

2 is a block diagram illustrating a connection state of a mobile communication relay system inside a building according to an exemplary embodiment of the present invention.

3 is a block diagram showing an internal configuration of an IMS.

Claims (5)

As a system for relaying mobile communication signals inside a building, Installed inside the building and converts a digital optical signal or an RF signal received from a base station or an RF repeater to a digital communication signal or outputs, or converts the input digital communication signal into a digital optical signal or an RF signal to the base station or RF repeater Transmitting IMS; An IRTS for converting and outputting an RF signal transmitted from a mobile communication terminal located in a building into a digital communication signal, or for converting an input digital communication signal into an RF signal and outputting the RF signal through a wireless antenna; And an IHS connected between the IMS and the IRTS to relay a digital communication signal. The IMS, IHS, and IRTS include both a UTP cable connection interface and an optical cable connection interface, and selectively transmit or receive a communication signal by using any one of the UTP cable or the optical cable, inside the building having multiple interfaces. Mobile communication relay system. The method of claim 1, It is connected between the IHS and the IRTS and relays a digital communication signal, and converts an RF signal transmitted from a mobile communication terminal located in a building into a digital communication signal and outputs the digital communication signal to the IHS, or a digital communication signal input from the IHS. IRIS for converting the signal into an RF signal and output through the wireless antenna; The IRIS has both a UTP cable connection interface and an optical cable connection interface, characterized in that the transmission and reception, mobile communication relay system in a building having multiple interfaces. The method according to claim 1 or 2, The IMS, the IRTS, the IRIS, and the IHS An FPGA for converting an input digital communication signal into a gigabit transmission format; An Ethernet converter converting a communication signal of a gigabit transmission format output from the FPGA into an Ethernet transmission format and outputting the same through a UTP cable; And a CWDM conversion unit converting a communication signal of a gigabit transmission format output from the FPGA into an optical communication transmission format of a CWDM method and outputting the same through an optical cable. And the FPGA selectively controls the Ethernet converter and the CWDM converter to transmit a communication signal through any one of the UTP cable and the optical cable. The method according to claim 1 or 2, The IHS An FPGA; An Ethernet converter converting a communication signal of a gigabit transmission format output from the FPGA into an Ethernet transmission format and outputting the same through a UTP cable; And a CWDM conversion unit converting a communication signal of a gigabit transmission format output from the FPGA into an optical communication transmission format of a CWDM method and outputting the same through an optical cable. The FPGA Output digital communication signal inputted through Ethernet transmission format or optical transmission format without changing transmission format, Selectively converting the Ethernet communication unit and the CWDM conversion unit to convert the digital communication signal of the Ethernet transmission format into the digital communication signal of the optical communication transmission format, and convert the digital communication signal of the optical communication transmission format into the digital communication signal of the Ethernet transmission format. A mobile communication relay system in a building having multiple interfaces, characterized in that for controlling. The method according to claim 1 or 2, The base station or RF repeater In-building mobile communication relay system having multiple interfaces, characterized in that for transmitting and receiving RF signals used in 2G, 3G, WiMAX mobile communication network.

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