KR101249894B1 - Mobile communication line expansion device in building using pof and gof - Google Patents

Abstract

The present invention relates to a mobile communication line expansion device using the POP and BOP in the building, and more specifically, in order to build a communication line inside the building to connect the RF cable, CCTV coaxial cable, UTP cable to one expansion device, The present invention relates to a mobile communication line extension device using a PO and a BOP in a building that enables a communication network to be operated efficiently and economically by using a PO to connect with another extension device.
According to the present invention, since each device required for the expansion of a communication network in a building can extend a service through a single expansion device, there is an advantage of simplifying installation and efficient and economical network operation.

Description

MOBILE COMMUNICATION LINE EXPANSION DEVICE IN BUILDING USING POF AND GOF}

The present invention relates to a mobile communication line expansion device using the POP and BOP in the building, and more specifically, in order to build a communication line inside the building to connect the RF cable, CCTV coaxial cable, UTP cable to one expansion device, The present invention relates to a mobile communication line extension device using POP and BOP in an interior of a building that can operate a communication network efficiently and economically by connecting with another extension device using an optical cable.

In-building relay systems that transmit communication signals in buildings such as apartments or offices often use optical communication cables. Optical communication cables include cables made of plastic optic fiber (POF) and cables made of glass optic fiber (GOF), which is preferred to in-built systems.

However, the mobile communication service using GOF enables long-distance signal transmission and establishes a low-noise communication network, while reducing investment efficiency due to an increase in line construction costs.

In recent years, in order to solve this problem of installation cost, a cable according to an individual communication system is often used.

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

As shown in Figure 1, in order to transmit a mobile communication signal or Internet signal, such as using a low-cost RF cable, CCTV coaxial cable, UTP cable to build a mobile communication network inside the building.

The antenna 11 installed in the RF repeater MHU 12 receives a signal of the RF communication frequency transmitted from the base station and transmits a signal to the RU1 (Remote Unit) 14 and the RU2 15 through the RF cable 13.

And even in the case of CCTV repeater MHU (22), the antenna 21 receives a signal of the RF communication frequency transmitted from the base station and transmits a mobile communication signal to the RU3 (24) in the building through the internal CCTV coaxial cable (23) .

In general, the CCTV coaxial cable 23 is also used to transmit the RF signal for mobile communication in the building.

Even in the case of the UTP repeater MHU 32, the antenna 31 receives a signal of an RF communication frequency transmitted from a base station and converts the signal into a digital signal, and converts the converted digital signal into an EHUB (Expansion) inside the building through the UTP cable 33. Hub Unit in Building (34), and the EHUB 34 transmits a digital signal to the Expansion Remote Unit (ERU) 35 again. The ERU 35 converts the digital signal into an analog signal and transmits the signal to a mobile communication terminal in the building.

The UTP repeater MHU 32, the EHUB 34, and the ERU 35 are all connected by a UTP cable 33.

As described above, the transmission of communication signals using different cables according to each communication method has a problem that the construction cost of the line is low, but the communication cable duct of the premises becomes very complicated and the distance to transmit the signal is limited. For example, in case of UTP transmission method, a hub should be installed every 100m according to the structure of the building, and in case of a repeater taking an RF distribution method such as an RF repeater or a CCTV repeater, the RU (14, 15, 24) should be installed continuously.

Therefore, there is a problem that additional costs are required to build a communication line in a large building, and the design of the line is complicated.

Republic of Korea Patent Application No. 2002-0001957 Republic of Korea Patent Application No. 2003-0028125

The present invention for solving the above problems is to install a plurality of expansion devices that can connect all of the RF cable, CCTV coaxial cable, UTP cable signal inside the building, by connecting each extension device to the optical communication network by the optical cable one An object of the present invention is to provide a mobile communication line extension device using POP and BOP in a building that can transmit and receive various kinds of communication signals in the line.

The present invention devised to solve the above-mentioned problems is an apparatus that converts an RF signal into an optical signal and outputs it through the optical cable 120, or converts the optical signal input through the optical cable 120 into an RF signal, RF signal for mobile communication service transmitted through RF cable 13 connected to RF repeater MHU 12, RF signal transmitted through CCTV coaxial cable 23 connected to CCTV repeater MHU 22, and UTP repeater MHU A first expansion device (100) for converting and outputting a digital signal for a mobile communication service or an Internet connection transmitted through an UTP cable (33) connected to the optical signal; By converting the optical signal input from the first expansion device 100 to an RF signal, among the RF relay RU1 (Remote Unit; 14), CCTV relay RU3 (24), UTP relay ERU (Expansion Remote Unit; 35) And a second expansion device 100 ′ outputting to any one or all of them, wherein the first expansion device 100 and the second expansion device 100 ′ are installed together in one building. Optical cable 120 is characterized in that any one of the POF cable or GOF cable.

The first expansion device (100) includes a PHY module (102) for receiving a digital signal transmitted from the UTP repeater MHU (32) to separate the baseband signal; A frequency converter 104 for converting a frequency of the RF signal transmitted from the RF repeater MHU 12 into an intermediate frequency (IF) band; An A / D 106 for converting an analog IF signal output from the frequency converter 104 into a digital signal; A D / A 108 which converts a digital signal into an analog IF signal and inputs it to the frequency converter 104; An FPGA 110 for digital signal processing and optic frame alignment of the electrical signal input through the A / D 106; An E / O 112 for converting the digital signal output from the FPGA 110 into an optical signal; An O / E 114 for converting an optical signal into a digital signal and inputting the digital signal to the FPGA 110; The optical signal output from the E / O 112 is transmitted to the second expansion device 100 'through the optical cable 120 or from the second expansion device 100' through the optical cable 120. And a small form-factor pluggable (SFP) 116 for receiving the input optical signal.

According to the present invention, since each device required for the expansion of a communication network in a building can extend a service through a single expansion device, there is an advantage of simplifying installation and efficient and economical network operation.

In addition, according to the present invention there is an effect that can use the optical communication network inside the building by using a POF cheaper installation cost than GOF.

1 is a block diagram showing a connection state of the in-building relay system according to the prior art.
Figure 2 is a block diagram showing a connection structure of the in-building relay system according to an embodiment of the present invention.
Figure 3 is a block diagram showing the internal configuration of the expansion device.

Hereinafter, with reference to the drawings will be described "an extension device for mobile communication line using the POP and BOP in the building" (hereinafter referred to as "expansion device") according to an embodiment of the present invention.

Figure 2 is a block diagram showing the connection structure of the in-building relay system according to an embodiment of the present invention, Figure 3 is a block diagram showing the internal configuration of the expansion device.

The expansion device (100, 100 ') of the present invention is installed inside the building, the first expansion device 100 and the second expansion device (100') is connected by an optical cable 120. The number of the first expansion device 100 and the second expansion device 100 'and the length of the optical cable 120 may vary depending on the size of the building and the arrangement of the service terminal.

POF and GOF are the materials that make up the optical cable. POF and GOF are the same in that they are used in optical communication networks, but the transmission distance and speed differ depending on the characteristics of the medium. In general, optical cables made of GOF can transmit data at speeds of 10Gbps up to a distance of up to 30-40km. By the way, the optical cable made of POF has a data transmission speed of up to 3Gbps, but the data transmission distance is only up to 500m. Therefore, GOF should be used when installing optical cables in a wide area such as outdoors, but when constructing an optical communication network in one building as in the present invention, it should be installed within a distance range that can sufficiently transmit data even using POF. Is possible. In particular, POF cables are inexpensive to build a system, and installation and maintenance are relatively easy compared to GOF.

In the present invention, the first expansion device 100 and the second expansion device 100 'is described as connecting to the optical cable 120 to transmit and receive data, the optical cable 120 is made of POF or GOF, depending on the section Can be used by mixing POF and GOF without special operation of expansion device (100, 100 ').

The first expansion device 100 is connected to the RF repeater MHU 12, CCTV repeater MHU 22, UTP repeater MHU 32, each component of the RF cable 13, as in the prior art described above, CCTV coaxial cable (23), UTP cable (33) is connected to send and receive communication signals.

In the case of the RF repeater MHU (12), the system of the internal communication room receives a signal of the RF communication frequency transmitted from the base station and transmits the RF signal to the first expansion device 100 through the RF cable (13). The RF signal consists of a communication signal for a second generation (2G) or third generation (3G) mobile communication service. After the first expansion device 100 passes the A / D 106 through the frequency converter 104 for converting the RF signal into the IF signal, the digital signal processed data in the FPGA 110 is transmitted through the optic frame. Aligned. The sorted data is converted into an optical signal through the E / O 112 and then transmitted to the second expansion device 100 ′ through the POF or GOF optical cable 120. The second expansion device 100 ′ converts the optical signal into an RF signal again and transmits the optical signal to the RF relay RU1 14 through the RF cable 13.

In the case of the CCTV repeater MHU (22), when the RF signal transmitted through the external antenna 21 to the first expansion device 100 through the CCTV coaxial cable 23, the frequency converter converts the RF signal into an IF signal After passing through A / D 106 via 104, the digitally signaled data within FPGA 110 is aligned via an Optic Frame. The sorted data is converted into an optical signal through the E / O 112 and then transmitted to the second expansion device 100 ′ through the POF or GOF optical cable 120. The second expansion device 100 ′ converts the optical signal into an RF signal again and transmits the optical signal to the CCTV repeater RU3 24 through the CCTV coaxial cable 23.

In the case of the UTP repeater MHU 32, when the digital signal is transmitted to the first expansion device 100 through the UTP cable 33, the first expansion device 100 converts the digital signal into an optical signal to convert the POF or GOF optical cable ( And transmits to the second expansion device 100 ′ through 120. The digital signal is composed of a signal for mobile communication service or a signal for internet connection. The second expansion device 100 ′ converts the optical signal into a digital signal and transmits the optical signal to the URU relay ERU 35 through the UTP cable 33 again.

Basically, the expansion device (100, 100 ') has an interface to connect the RF cable (13), CCTV coaxial cable (23), UTP cable (33), mutual conversion of digital signals and analog signals, optical signals and electrical It has functions such as signal conversion and optical cable connection.

Both expansion devices (100, 100 ') is a device for performing such a function and consists of the same components, in the present invention will be described based on the first expansion device (100).

As shown in Figure 3, the first expansion device 100 is a PHY module 102 for separating the baseband signal by processing the digital signal transmitted from the UTP repeater MHU (32), RF repeater MHU (12) and CCTV repeater And a frequency converter 104 for converting the frequency of the RF signal transmitted from the MHU 22 into an IF signal which is an intermediate frequency band. The digital communication signal output from the PHY module 102 is input to the field programmable gate array (FPGA) 110, and the IF signal output from the frequency converter 104 passes through the A / D (analog / digital converter; 106). The signal is converted into a digital communication signal and input to the FPGA 110.

The digital signal output from the FPGA 110 is converted to an optical signal while passing through an E / O (optoelectric converter; 112) to an optical cable 120 connected to one end of a small form-factor pluggable (SFP) 116. It is carried out.

The other end of the POF or GOF optical cable 120 is connected to the SFP of the second expansion device 100 ', and the signals are separated in the reverse order as described above, so that each RF repeater RU1 (14) and CCTV repeater RU3 ( 24) to the ERU 35 for the UTP repeater.

Conversely, data output from the second expansion device 100 'and loaded on the POF or GOF optical cable 120 passes through the SFP 116 of the first expansion device 100 and passes through an O / E (photoelectric converter; 114). Is converted into a digital signal. The converted digital signal is converted to a complete digital signal after executing De-MUX of the Optic Frame in the FPGA 110, and is output to the MHU3 34 of the UTP repeater 32 through the PHY module 102, or D / A. (Digital / Analog Converter) 108 is converted into an IF signal and output to the RF Repeater MHU 12 or the CCTV Repeater MHU 22.

As described above, the present invention receives all signals output from the RF cable, the CCTV coaxial cable, and the UTP cable, converts them into optical signals, and transmits and receives optical signals through the POF or GOF optical cable network inside 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.

100, 100 ': Expansion device 102: PHY module
104: frequency converter 106: A / D
108: D / A 110: FPGA
112: E / O 114: O / E
116: SFP 120: optical cable

Claims (2)

A device for converting an RF signal into an optical signal and outputting it through an optical cable 120, which is either a POF cable or a GOF cable, or by converting an optical signal input through the optical cable 120 to an RF signal,
RF signal for mobile communication service transmitted through RF cable 13 connected to RF repeater MHU 12, RF signal transmitted through CCTV coaxial cable 23 connected to CCTV repeater MHU 22, and UTP repeater MHU A first expansion device (100) for converting and outputting a digital signal for a mobile communication service or an Internet connection transmitted through an UTP cable (33) connected to the optical signal;
Installed in the same building as the building in which the first expansion device 100 is installed, converts the optical signal input from the first expansion device 100 into an RF signal for RF relay RU1 (Remote Unit; 14), CCTV And a second expansion device 100 ′ outputting to any one or more or all of the relay RU3 24 and the UTP relay ERU (Expansion Remote Unit; 35).
The first expansion device 100
A PHY module 102 for receiving a digital signal transmitted from the UTP repeater MHU 32 and separating a baseband signal;
A frequency converter 104 for converting a frequency of the RF signal transmitted from the RF repeater MHU 12 into an intermediate frequency (IF) band;
An A / D 106 for converting an analog IF signal output from the frequency converter 104 into a digital signal;
A D / A 108 which converts a digital signal into an analog IF signal and inputs it to the frequency converter 104;
An FPGA 110 for digital signal processing and optic frame alignment of the electrical signal input through the A / D 106;
An E / O 112 for converting the digital signal output from the FPGA 110 into an optical signal;
An O / E 114 for converting an optical signal into a digital signal and inputting the digital signal to the FPGA 110;
The optical signal output from the E / O 112 is transmitted to the second expansion device 100 'through the optical cable 120 or from the second expansion device 100' through the optical cable 120. And a Small Form-Factor Pluggable (SFP) 116 for receiving an input optical signal. delete

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