KR20120057114A - Access point with integrated mobile communication antenna and unified optical repeater using the same - Google Patents

Abstract

PURPOSE: An AP(Access Point) syntagmatically including mobile antenna and integrated optical repeater are provided to integrate a repeater with integrated apparatus by integrating AP for access a mobile communication service antenna and wireless internet connection. CONSTITUTION: A donor unit creates one optical signal. A remote unit(410) receives the optical signal through one optical line. The remote unit changes the optical signal into an RF signal. Integrated AP separates an RF mobile communication signal and an RF internet signal from the RF signal. The integrated AP wirelessly emits the RF mobile communication signal. The integrated AP changes the RF internet signal into a mobile LAN(Local Area Network) signal.

Description

ACCESS POINT WITH INTEGRATED MOBILE COMMUNICATION ANTENNA AND UNIFIED OPTICAL REPEATER USING THE SAME}

The present invention relates to an access point integrally equipped with a mobile communication antenna and an optical relay apparatus including the same, and more particularly, to an access point integrating an existing mobile communication service antenna and an access point for wireless Internet access, and one of them. The present invention relates to an optical relay apparatus capable of integrating and providing a mobile communication service and a wireless LAN Internet service through a single repeater.

In general, since a repeater for mobile communication is responsible for amplifying and transmitting a signal of a base station, existing repeaters cannot provide wired and wireless Internet services (LAN, WiFi, etc.).

Therefore, the mobile communication service and the wired / wireless Internet service which are currently being operated are implemented by separately installing a repeater for providing each service or by integrating the optical lines of the repeaters.

However, the implementation method has a problem that a lot of cost in the equipment construction.

In order to solve this problem, a gigabit wired signal can be transmitted to a digital framer of an existing mobile communication transmission repeater, and a wireless communication access point and an access point for a wireless Internet are built in. The problem of having to install separately was improved.

Hereinafter, a conventional optical relay device will be described with reference to FIG. 1.

Conventional optical relay device is a RF signal (synchronous signal and asynchronous signal) of the mobile communication to process and relay the signals transmitted and received through the synchronous / asynchronous antenna 60 for mobile communication and the access point 70 for the wired and wireless Internet And the Ethernet signal of the wired Internet (including an optical Ethernet signal or a wide area network (WAN) signal) are combined into an optical signal, and then restored to an original signal.

To this end, the conventional optical relay device includes a donor unit 21 and a media gateway 23 in the optical signal coupling module 20 to convert an RF signal of a mobile communication and an Ethernet signal of a wired / wireless internet into an optical signal. By coupling through the optical signal combiner 25, two optical wavelengths are transmitted to one optical line.

In addition, the optical signal separation module 40 separates the optical signal coupled from the optical signal separator 45 and transmits the optical signals separated by the optical signal separator 45 to different optical lines.

In this case, the optical signal coupling module 20 and the optical signal separation module 40 are used to connect the optical cable to the donor part 21 and the remote part 41 and the media gateways 23 and 43, which are detailed components. As a port, a small-form-factor pluggable (SFP) should be provided, and the use of expensive optical signal combiner 25 and optical signal separator 45 will inevitably increase the installation cost.

In addition, the conventional optical relay device has an inefficient problem because two optical wavelengths, which are resources of an optical line, must be utilized.

In addition, since the conventional optical relay device implements a service by connecting different cables to each service antenna, additional construction costs are incurred. For example, the synchronous / asynchronous antenna 60 for a mobile communication service is connected through a coaxial cable 51, and the access point 70 is connected through a UTP cable 53, so each cable must be provided with a problem. There is this. In addition, even if the conventional optical relay device is provided with a plurality of service antennas, there is a problem that its utilization is inferior because only transmit and receive signals corresponding to each service.

The present invention was devised to solve the above problems, and by integrating an existing mobile communication service antenna and an access point for a wireless Internet connection and implementing it integrally in one repeater, the mobile communication service and the wired / wireless Internet need only be installed. It is an object of the present invention to provide a mobile communication and wired and wireless Internet integrated optical relay apparatus and method that can provide integrated services.

Another object of the present invention is to provide an integrated access point capable of accessing an antenna and a wireless LAN by integrating a mobile communication service antenna and an access point for wireless Internet access.

To this end, according to the first aspect of the present invention, a mobile communication and wired and wireless Internet integrated optical relay device of the present invention, the donor unit for receiving a mobile communication signal and the Internet signal, respectively, to generate a single optical signal; A remote unit for receiving the optical signal through one optical line and converting the optical signal into an RF signal; Receiving the RF signal and separating the RF mobile communication signal and the RF Internet signal from the RF signal, the RF mobile communication signal is wirelessly radiated, and the RF Internet signal includes an integrated access point to convert and transmit the WLAN Internet signal Characterized in that.

According to a second aspect of the invention, the integrated access point of the present invention, the separation unit for separating the mobile communication signal and the Internet signal from the RF signal received through one coaxial cable; A digital converter for converting the Internet signal separated by the separator from an RF format to a digital format; A wireless internet signal converting unit converting the digital internet signal converted by the digital converting unit into a wireless LAN internet signal; And a wireless Internet service antenna for wirelessly radiating the mobile communication signal separated by the separation unit or transmitting the wireless LAN internet signal converted by the wireless internet signal conversion unit.

According to a third aspect of the present invention, a mobile communication and wired and wireless Internet integrated optical relay method according to the present invention comprises: (a) receiving a mobile communication signal for providing a mobile communication service and an internet signal for providing an internet service, respectively; step; (b) generating the received mobile communication signal and the Internet signal into one optical signal; (c) converting the generated one optical signal into an RF signal; (d) receiving the RF signal and separating the RF mobile communication signal and the RF internet signal from the RF signal, and then wirelessly radiating the RF mobile communication signal and converting the RF internet signal into a wireless LAN internet signal and transmitting the same. It is characterized by including.

According to a fourth aspect of the present invention, a mobile communication and wired and wireless Internet integrated relay method in an integrated access point of the present invention is an integrated relay method for unifying and providing a mobile communication service and an Internet service using one access point. (a) receiving a signal combining a mobile communication signal for providing the mobile communication service and an internet signal for providing the internet service through one coaxial cable connected to the access point; (b) separating a mobile communication signal and an internet signal from the combined signal.

According to the present invention, the service antenna for mobile communication and the access point for wireless internet are integrated into one relay device, so that service integration and provision of not only mobile communication services but also wired and wireless Internet services (Ethernet, WiFi service, etc.) can be provided. There is.

In addition, by implementing the service antenna for the mobile communication and the access point for the wireless Internet integrally there is an effect that can transmit and receive signals for the wired and wireless Internet as well as mobile communication through one antenna.

In addition, since it is possible to provide a wireless Internet service within the existing mobile communication coverage (coverage), it is possible to make full use of the installed infrastructure environment to improve the communication service quality.

1 is a view showing an optical relay device according to the prior art.
2 is a view showing an integrated optical relay device according to an embodiment of the present invention.
3 is a view showing a connection relationship between an integrated optical relay and an antenna according to an exemplary embodiment of the present invention.
Figure 4 is a detailed view of the donor portion of the integrated optical relay device according to an embodiment of the present invention.
5 is a detailed view of a remote unit of the integrated optical relay device according to the embodiment of the present invention.
6 is a view showing a detailed structure of the coupling portion in the remote portion of FIG.
FIG. 7 is a view illustrating a structure in which a coupling part may be divided in the remote part of FIG. 5. FIG.
8 is a detailed view of an access point of the integrated optical relay device according to the embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The configuration of the present invention and the operation and effect thereof will be clearly understood through the following detailed description. Prior to the detailed description of the present invention, the same components will be denoted by the same reference numerals even if they are displayed on different drawings, and the detailed description will be omitted when it is determined that the well-known configuration may obscure the gist of the present invention. do.

The mobile communication signal referred to below refers to a signal for providing a mobile communication service including a 2G (CDMA) signal, a 3G (WCDMA) signal, a 4G (LTE) signal, and the like.

Internet signals are collectively referred to as signals for providing wired and wireless Internet services such as gigabit Ethernet, LAN, Wi-Fi, and Wibro.

An embodiment of the present invention relates to a relay device that can provide a combination of the above-mentioned mobile communication signal and the Internet signal, 2G / Internet, 3G / Internet, 4G / Internet, 2G / 3G / Internet, 3G / 4G / The integrated relay service can be selectively provided in the form of Internet.

2 is a diagram illustrating an integrated optical relay device according to an exemplary embodiment of the present invention.

Integrated optical relay device according to an embodiment of the present invention is a relay device implemented as a single module by integrating the antenna and the transmission and reception device to reduce the power consumed in the operation of the base station when installing the mobile communication base station.

The optical relay device according to the embodiment of the present invention includes a donor unit 210, a remote unit 410, and an integrated access point 600 in one module.

Conventionally, it is composed of three modules as shown in 20 of FIG. That is, the donor unit converting the mobile communication signal into the optical signal, the media gateway converting the internet signal into the optical signal, and the optical signal combiner combining the respective optical signals are implemented. The equipment, the donor part 210 was configured.

The donor unit 210 is connected to the base station 100 to receive a signal for providing a mobile communication service (hereinafter, referred to as a mobile communication signal) and an internet signal for wired / wireless internet from the base station 100 to receive a single optical signal. To combine.

In FIG. 2, mobile communication signals include synchronous (CDMA), asynchronous (WCDMA) signals, and the like, and internet signals include optical Ethernet signals, WAN Ethernet signals, and the like.

The remote unit 410 receives an optical signal coupled by the donor unit 210 through one optical line 310 and converts the received optical signal into an RF signal. The remote unit 410 transmits the converted RF signal to the integrated access point 600 through the coaxial cable 510.

After the conventional remote unit passes through the optical signal separator 45 of FIG. 1, the remote unit converts the optical signal into a digital signal, and then converts the optical signal into a synchronous / asynchronous RF signal, and converts the optical signal into a WAN signal in the media gateway. Sent to. However, the present invention can transmit the signal to one coaxial cable by configuring the above three devices as one device, the remote unit 410.

The integrated access point 600 separates the RF signal received from the remote unit 410 to provide an integrated service. That is, the integrated access point 600 wirelessly radiates through the mobile communication service antenna 620 and the integrated service antenna 630 by applying the RF format received from the remote unit 410 in the case of a mobile communication signal, and internet signal. In the case of converting the signal of the RF format into a wireless LAN signal and transmits through the wireless Internet service antenna 630.

The integrated access point 600 according to an exemplary embodiment of the present invention includes a wireless Internet service antenna 630 in which an antenna function for a mobile communication service and an antenna function for a wireless Internet service are integrally formed. May be provided separately to provide both mobile communication service and wireless Internet service through a single service antenna.

Accordingly, the optical relay device according to an embodiment of the present invention can implement various services according to multiplexing of wired and wireless services through one relay module. In particular, since it can be implemented by using a repeater for the existing mobile communication, facility investment and existing communication infrastructure can be utilized as it is.

In addition, since the optical relay device according to an embodiment of the present invention can implement a mobile communication service and a wired / wireless internet service through one coaxial cable 510 as shown in FIG. 4, a separate additional cable (UTP cable) The number of unnecessary and redundant service antennas can be reduced.

Next, a detailed component of an optical relay device capable of integrating a mobile communication service and a wired / wireless internet service through a single module will be described.

4 is a detailed view of a donor part of the optical relay device according to the embodiment of the present invention.

The donor unit 210 according to an exemplary embodiment of the present invention is characterized by a configuration that converts two signals, that is, a mobile communication signal and an Internet signal, into a digital signal for use.

To this end, the donor 210 includes a digital converter 212 and an optical signal converter 214.

The digital converter 212 lowers the mobile communication signal received from the base station 100 to the intermediate frequency IF and converts the digital signal into digital signals through A / D (analog / digital) conversion. The Ethernet signal input to the optical or WAN is also converted into a digital signal. In addition, the digital converter 212 frames each digital signal through one framer. The framed signals are serially aligned and output.

The optical signal converter 214 converts the digital signal output from the digital converter 212 into an optical signal to generate one optical wavelength. The generated optical signal is transmitted to the remote unit 410.

Therefore, the donor part 210 may be matched with the optical signal coupling part (20 in FIG. 1) of the conventional optical relay device. In the conventional optical signal coupling part (20 in FIG. 1), the donor part (21 in FIG. In the present invention, the mobile communication signal and the Internet signal are converted into optical signals through the donor unit 210, that is, one SFP. This can reduce the cost of equipment due to the use of SFPs.

5 is a detailed view of a remote unit of an optical relay device according to an exemplary embodiment of the present invention.

The remote unit 410 may include a digital converter 412, a wireless signal converter 414, and a combiner 416 to correspond to the donor unit 210. Although not shown in FIG. 6, the remote unit 410 may further include an optical signal processing unit that performs a predetermined light processing before digitally converting the optical signal received from the donor unit 210.

The digital converter 412 converts the received optical signal into a digital signal, serially aligns the converted digital signal, and frames the converted digital signal. In addition, the mobile communication signal and the Internet signal are separated from the framed digital signal, converted into an intermediate frequency IF, and output.

The wireless signal converter 414 converts each signal output from the digital converter 412 into an RF signal from an intermediate frequency (IF) signal. For example, an RF synchronization signal (800 to 900MHz), an RF asynchronous signal (1900 to 2100MHz), and an RF Ethernet signal (2400 to 2480MHz) can be output.

As such, the wireless signal converter 414 may separately include a WiFi MIMO (Multiple Input Multiple Output) chip for converting a WiFi signal from the Internet signal into an RF signal.

The combiner 416 combines each RF signal converted by the radio signal converter 414 and sends the combined RF signals to the integrated access point 600 through one coaxial cable 510.

Remote unit 410 is configured as compared with the conventional remote unit and the optical signal separation part (40 in FIG. 1) including the media gateway, optical coupler, but conventionally requires a separate optical coupler and two SFP of the present invention In an embodiment, a mobile communication signal and an internet signal can be transmitted without using an optical coupler even using one SFP.

6 is a view showing a detailed structure of the coupling portion in the remote portion of FIG.

As shown, the coupling unit 416 transmits both mobile communication signals (synchronous or asynchronous signals) and Internet signals converted to RF signals in one coaxial cable, as well as a bias for supplying the operating power of the integrated access point. A bias-T function may be mounted.

In general, the bias tee (Bias-T) refers to a structure branched in an English T-shape to the RF signal applying line for power supply, and may be applied when combining the RF signal and the DC bias voltage.

For example, the coupling unit 416 may be implemented as a coupler having a built-in bias tee function.

According to the structure of FIG. 6, the coupling unit 416 includes a mobile communication signal input terminal 416a for receiving a mobile communication signal, an internet signal input terminal 416b for receiving an internet signal, a DC voltage input terminal 416c, Coupling unit 416e for coupling the mobile communication signal applied from the mobile communication signal input terminal 416a and the internet signal applied from the internet signal input terminal 416b to one cable, the mobile communication signal and the internet signal, and the DC bias. An output terminal 416d for integrating and outputting a voltage in one cable is provided.

At this time, the Internet signal input terminal 416b may be implemented as one, but when there are several signal channels, the signals of each channel are combined and coupled to one cable to which a mobile communication signal is applied. In this case, the circuit further includes a coupling circuit 416f for coupling the Internet signal of each channel.

7 shows a structure in which the coupling portion is branched.

The coupling unit 416 may be applied to a structure in which power is distributed and distributed when the output is high.

To this end, the coupling unit 416 divides the signal applied through the mobile communication signal input terminal 416a into a plurality of branches, and provides a coupling unit 416e for coupling the WiFi Internet signal for each channel to each branched cable. Equipped.

Therefore, the mobile communication signal applied through the mobile communication signal input terminal 416a and the internet signal and DC bias voltage applied through the internet signal input terminal 416b and the DC voltage input terminal 416c are coupled to each branched cable. The mobile terminal outputs a signal combining both the mobile communication signal, the Internet signal, and the voltage to the corresponding output terminals 416d-1, 416d-2, and 416d-3.

8 is a detailed view of the integrated access point of the optical relay device according to the embodiment of the present invention.

The integrated access point 600 according to the embodiment of the present invention includes an antenna module for transmitting and receiving an existing mobile communication and an access point (AP) for providing a wireless Internet service (particularly, a WiFi service). It can also be used as an access point for connecting to a wireless network.

As a specific configuration thereof, the integrated access point 600 may use the separation unit 612, the digital conversion unit 614, the wireless Internet signal conversion unit 616, the mobile communication service antenna 620, and the wireless Internet service antenna 630. It may include.

The mobile communication service antenna 620 includes a synchronous antenna for transmitting and receiving a synchronous signal in a mobile communication signal, an asynchronous antenna for transmitting and receiving an asynchronous signal, and the like.

The wireless Internet service antenna 630 includes an antenna function for transmitting and receiving mobile communication signals and an antenna function for transmitting and receiving wireless internet signals.

The separator 612 separates a signal received through one coaxial cable. Through this, the mobile communication signal (RF mobile communication signal) input as the RF signal from the separating unit 612 is wirelessly radiated through the mobile communication service antenna 620, and the internet signal (RF Internet signal) input as the RF signal is digital. Transfer to the conversion unit 614. The DC bias voltage is then supplied to the operating power source of the integrated access point 600.

The digital converter 614 converts the RF internet signal received through the separator 612 into a digital internet signal.

The wireless internet signal converter 616 converts the digital internet signal converted by the digital converter 614 into a desired wireless internet signal, and transmits the converted wireless internet signal to the wireless internet service antenna 630. Here, the digital converter 614 and the wireless Internet signal converter 616 may be configured as a WiFi chip for converting the RF Internet signal into a WiFi signal.

Then, the integrated service antenna 630 transmits the wireless LAN internet signal received from the wireless internet signal converter 616 to perform the wireless internet service.

The integrated access point 600 according to the embodiment of the present invention configured as described above may separate and transmit RF signals received from the remote unit 410 and transmit and receive them through a corresponding service antenna to provide not only mobile communication services but also wired and wireless Internet services. .

The foregoing description is merely illustrative of the present invention, and various modifications may be made by those skilled in the art without departing from the spirit of the present invention. Therefore, the embodiments disclosed in the specification of the present invention are not intended to limit the present invention. The scope of the present invention should be construed by the claims below, and all techniques within the scope equivalent thereto will be construed as being included in the scope of the present invention.

In the related art, the mobile communication service antenna and the access point for WiFi are separately provided, but the present invention has been restricted. However, the present invention reduces the number of installation of the antenna and the access point by integrally implementing the mobile communication service antenna and the access point for WiFi. Efficient network design with reduced investment cost is possible, and it is effective to provide WiFi service by making full use of mobile communication infrastructure.

100: base station 210: donor part
310: optical path 410: remote portion
510: coaxial cable 600: integrated access point
620: mobile communication service antenna 630: integrated service antenna
212, 412, and 614: digital converter 214: optical signal converter
640: wireless Internet service antenna 414: wireless signal conversion unit
416: coupling portion 612: separation portion
616: wireless Internet signal conversion unit

Claims (19)

A donor unit configured to receive a mobile communication signal and an internet signal, respectively, and generate one optical signal;
A remote unit for receiving the optical signal through one optical line and converting the optical signal into an RF signal;
Receiving the RF signal and separating the RF mobile communication signal and the RF Internet signal from the RF signal, the RF mobile communication signal is wirelessly radiated, and the RF Internet signal includes an integrated access point to convert and transmit the WLAN Internet signal Integrated optical relay device, characterized in that. The method of claim 1,
And the remote unit and the integrated access point are connected through a single coaxial cable. The method of claim 1,
The donor part
A digital converter configured to convert the mobile communication signal and the internet signal into digital signals and frame the digital signals; And
And an optical signal converter for converting the framed digital signal into an optical signal. The method of claim 1,
The remote unit
A digital conversion unit for receiving an optical signal from the donor unit and converting the optical signal into a digital signal and separating a mobile communication signal and an internet signal from the digital signal;
A wireless signal converter for converting the mobile communication signal and the Internet signal separated by the digital converter into RF signals; And
And a combiner for combining the respective RF signals converted by the radio signal converter and transmitting the combined RF signals to the integrated access point. The method of claim 1,
The integrated access point is
And a WiFi chip for converting the RF Internet signal into a WiFi signal. The method of claim 4, wherein
The coupling portion
A DC bias tee function for supplying operational power to the integrated access point,
And combining the mobile communication signal, the internet signal, and the DC bias voltage to provide the integrated access point. A separating unit separating a mobile communication signal and an internet signal from an RF signal received through one coaxial cable;
A digital converter for converting the Internet signal separated by the separator from an RF format to a digital format;
A wireless internet signal converting unit converting the digital internet signal converted by the digital converting unit into a wireless LAN internet signal; And
And a wireless internet service antenna for wirelessly radiating a mobile communication signal separated by the separating unit or transmitting a wireless internet signal converted by the wireless internet signal converting unit. The method of claim 7, wherein
And the RF signal received through the one coaxial cable is a signal in which a mobile communication signal and an internet signal are combined. The method of claim 7, wherein
The wireless LAN Internet signal is an integrated access point, characterized in that the WiFi signal. The method of claim 7, wherein
The wireless Internet service antenna
And a mobile communication service antenna function for wirelessly radiating the mobile communication signal and a wireless internet service antenna function for transmitting the internet signal. (a) receiving a mobile communication signal for providing a mobile communication service and an internet signal for providing an internet service, respectively;
(b) generating the received mobile communication signal and the Internet signal into one optical signal;
(c) converting the generated one optical signal into an RF signal;
(d) receiving the RF signal and separating the RF mobile communication signal and the RF internet signal from the RF signal, and then wirelessly radiating the RF mobile communication signal and converting the RF internet signal into a wireless LAN internet signal and transmitting the same. Integrated optical relay method comprising a. The method of claim 11,
Step (b) is
(b-1) converting the mobile communication signal and the Internet signal into a digital signal and framing each;
(b-2) converting the framed digital signal into an optical signal. The method of claim 11,
The step (c)
(c-1) converting the one optical signal into a digital signal and inversely framing the converted digital signal to separate the mobile communication signal from the Internet signal;
(c-2) converting the mobile communication signal and the Internet signal into RF signals, respectively;
(c-3) combining the converted RF signals and transmitting the combined RF signals to the integrated access point. The method of claim 11,
Step (c-3) is
And a bias voltage to operate the integrated access point and the converted RF signals are combined and provided to the integrated access point. The method of claim 11,
The step (d)
Integrated optical relay method, characterized in that for receiving the RF signal through one coaxial cable. An integrated relay method for integrating and providing mobile communication services and Internet services using a single access point,
(a) receiving a signal combining a mobile communication signal for providing the mobile communication service and an internet signal for providing the internet service through one coaxial cable connected to the access point;
(b) separating a mobile communication signal and an internet signal from the combined signal. The method of claim 15,
In step (a), the combined signal is characterized in that the RF format. 17. The method of claim 16,
and (c) transmitting the separated mobile communication signal and the Internet signal through an antenna. The method of claim 18,
The step (c)
Converting the internet signal from an RF format to a digital format;
Converting the internet signal converted into the digital format into a wireless LAN internet signal;
And transmitting the wireless internet signal through the antenna.

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