JP2020198582A - Frequency expansion dispersion antenna system and frequency expansion method - Google Patents

Abstract

To provide a frequency expansion antenna system capable of expanding at least one new service frequency band in addition to an existing service frequency band by using a WDM technology.SOLUTION: A frequency expansion dispersion antenna system includes: an additional master unit for transmitting a downlink optical coupling signal obtained by coupling a first downlink optical signal of an existing service frequency band received through a first new optical line with a second downlink optical signal of a new service frequency band through a first existing optical line 200; an integrated hub for dispersively transmitting the downlink optical coupling signal through a second existing optical line 210; and an additional remote unit for receiving the downlink optical coupling signal from the integrated hub to separate it into the first downlink optical signal and the second downlink optical signal, transmitting the first downlink optical signal to an existing remote unit through a second new optical line 512, and generating a second RF communication signal on the basis of the second downlink optical signal to provide a service.SELECTED DRAWING: Figure 3

Description

The present invention relates to frequency expansion, and more particularly to a frequency expansion distributed antenna system for relaying a communication signal between a base station and a user terminal, and a frequency expansion method.

With the development of mobile communication, the amount of mobile communication used by users is rapidly increasing, and users want to receive stable communication services without being restricted by time and space. However, due to restrictions such as the limited output of the base station, the location of the base station, and the surrounding terrain, there is a problem that it is difficult for the operator to provide smooth communication services to the user due to the occurrence of shaded areas. A distributed antenna system (Distributed Antenna System, hereinafter referred to as "DAS") is used as a plan for the above. DAS is installed in areas where radio waves cannot be received or are difficult to receive, such as inside buildings, underground buildings, subways, tunnels, apartment complexes in residential areas, stadiums, etc., and it is difficult for base station signals to reach. By providing communication services to the shaded area, the coverage of the base station is expanded, and the master unit connected to the base station by communication and the master unit are connected to the master unit via an optical transmission medium to communicate with the user terminal. Consists of at least one remote device connected by.

According to such a conventional DAS, optical lines are systematically installed when a normal building is newly constructed in a building, and when newly or additionally installed in an already built building, it costs a lot of money and time. That is the problem.

Korean Patent Publication No. 10-2014-01211551

The problem to be solved by the present invention is to solve the above-mentioned drawbacks, and possesses an optical line integration module using a wavelength division multiplexing (WDM) technology. The purpose is to provide a frequency expansion antenna system and a frequency expansion method that enable expansion of at least one new service frequency band in addition to the existing service frequency band by using low-cost new service equipment. is there.

The frequency expansion distributed antenna system according to the present invention is a downlink light that combines a first downlink optical signal in the existing service frequency band and a second downlink optical signal in the new service frequency band received via the first new optical line. An additional master unit that transmits the coupled signal via the first existing optical line, an integrated hub that distributes and transmits the downlink optical coupled signal via the second existing optical line, and the downlink from the integrated hub. The optical coupling signal is received and separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is transmitted to the existing remote unit via the second new optical line. It is characterized by including an additional remote unit that generates a second RF communication signal based on the second downlink optical signal and provides a service.

The additional master unit receives an RF signal, an IF signal, or a digitally converted signal as a mobile communication signal of the new service frequency band from the second base station, and the RF signal or the IF signal is downlink. A digital signal converter that converts the downlink digital signal into a digital signal and outputs it, and outputs the digitally converted downlink signal as it is, and a first digital processing that processes the downlink digital signal to generate a digital frame capable of optical transmission. The unit, the first lightning / photoelectric conversion unit that generates the second downlink optical signal by lightning-converting the generated digital frame capable of optical transmission, the first downlink optical signal, and the second downlink. The additional remote unit includes a first WDM that transmits the optical coupled signal obtained by coupling the optical signals to the integrated hub via the first existing optical line, and the additional remote unit is via the second existing optical line. The transmitted downlink optical coupling signal is separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is sent to an existing remote unit via the second new optical line. A second WDM to be transmitted, a second lightning / photoelectric conversion unit that photoelectrically converts the separated second downlink optical signal to generate a downlink digital signal, and a second digital processing unit that processes the downlink digital signal. And an RF conversion unit that RF-converts the processed downlink digital signal to generate the second RF communication signal.

The frequency expansion distributed antenna system converts the mobile communication signal of the existing service frequency band serviced from the first base station into the first downlink optical signal converted into an optical frame, and via the first new optical line. An existing master unit to be transmitted to the additional master unit, an existing remote unit that generates and transmits a first RF communication signal based on the first downlink optical signal, the first RF communication signal from the existing remote unit, and the above. A multiplexer that frequency-multiplexes the second RF communication signal from the additional remote unit to acquire the frequency-multiplexed RF signal and transmits the frequency-multiplexed RF signal to the service coverage region via an antenna can be further included.

The frequency expansion distributed antenna system according to another embodiment of the present invention transmits the first uplink optical signal in the existing service frequency band and the second uplink optical signal in the new service frequency band received via the second new optical line. The at least one additional remote unit that couples to generate at least one uplink optical coupling signal and transmits over a second existing optical line and the at least one uplink optical coupling from the at least one additional remote unit. The integrated hub that integrates the signals and transmits them via the first existing optical line and the uplink optical coupling signal from the integrated hub are separated into a first uplink optical signal and a second uplink optical signal. The first uplink optical signal is transmitted to an existing master unit via a first new optical line, and includes an additional master unit that photoelectrically converts the second uplink optical signal to generate an uplink digital signal. It is a feature.

The additional remote unit has a second digital processing unit that processes the second uplink RF signal to generate the uplink digital signal, and an optical conversion of the uplink digital signal to obtain the second uplink optical signal. The output second lightning / photoelectric conversion unit, the first uplink optical signal from the existing remote unit, and the second uplink optical signal are combined to generate an uplink optical coupling signal, and the second existing optical line is generated. The additional master unit separates the uplink optical coupling signal from the integrated hub into a first uplink optical signal and a second uplink optical signal, including a second WDM that is transmitted to the integrated hub via. The first uplink optical signal is transmitted to the existing master unit via the first new optical line, and the second uplink optical signal is output from the first WDM and the second uplink from the first WDM. The first lightning / photoelectric conversion unit that photoelectrically converts the link optical signal to generate the uplink digital signal, and the uplink digital signal is transmitted to the second base station or converted into an RF signal or an IF signal. It can include a digital signal conversion unit to be transmitted to the second base station.

The frequency expansion distributed antenna system includes a multiplexer that demultiplexes the RF signal received via the antenna and outputs the first and second uplink RF communication signals, respectively, and the first uplink RF communication signal. Based on this, the existing remote unit that generates the first uplink optical signal and provides it to the additional remote unit via the second new optical line, and the first uplink optical signal from the additional master unit are described. It can further include the existing master unit which is received via the first novel optical line, converted into a mobile communication signal and transmitted to the first base station.

The frequency expansion distributed antenna system according to still another embodiment of the present invention is a first downlink optical signal in the existing service frequency band and a second downlink optical signal in the new service frequency band received via the first novel optical line. The downlink optical coupling signal is transmitted via the first existing optical line, the input uplink optical coupling signal is separated into the first uplink optical signal and the second uplink optical signal, and the first uplink optical signal is separated. The signal is an additional master unit that transmits the first new optical line to the existing master unit and photoelectrically converts the second uplink optical signal to generate an uplink digital signal, and the downlink optical coupling signal is transmitted to the second existing ray. Receives the integrated hub and the downlink optical coupled signal from the integrated hub, which are distributed and transmitted over the path, integrate at least one uplink optical coupled signal, and transmit over the first existing optical line. Then, it is separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is transmitted to the existing remote unit via the second new optical line, and the second downlink optical signal is transmitted. A second RF communication signal is generated based on the signal to provide a service, and a first uplink optical signal in the existing service frequency band and a second uplink in the new service frequency band received via the second new optical line are provided. It is characterized by including an additional remote unit that combines optical signals to generate at least one uplink optical coupling signal and transmits it via the second existing optical line.

The frequency expansion method according to another aspect of the present invention is a down link in which a first downlink optical signal in the existing service frequency band and a second downlink optical signal in the new service frequency band received via the first novel optical line are combined. The step of transmitting the link optical coupling signal via the first existing optical line, the step of distributed transmission of the downlink optical coupling signal via the second existing optical line, and the step of receiving the downlink optical coupling signal and performing the above. Separated into a first downlink optical signal and the second downlink optical signal, the first downlink optical signal is transmitted to an existing remote unit via a second new optical line, and is based on the second downlink optical signal. It is characterized by including a stage of generating a second RF communication signal and providing a service.

The frequency expansion method according to another embodiment of the present invention combines the first uplink optical signal of the existing service frequency band and the second uplink optical signal of the new service frequency band received via the second new optical line. At least one uplink optical coupling signal is generated and transmitted via the second existing optical line, and the at least one uplink optical coupling signal is integrated and transmitted via the first existing optical line. The uplink optical coupling signal is separated into a first uplink optical signal and a second uplink optical signal, and the first uplink optical signal is transmitted to the existing master unit via the first new optical line. It is characterized by including a step of photoelectrically converting a second uplink optical signal to generate an uplink digital signal.

In the downlink communication mode, the frequency expansion method according to still another aspect of the present invention includes a first downlink optical signal in the existing service frequency band received via the first new optical line and a second down in the new service frequency band. A step of transmitting a downlink optical coupled signal in which a link optical signal is coupled via a first existing optical line, a step of distributed transmission of the downlink optical coupled signal via a second existing optical line, and the downlink optical The combined signal is received and separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is transmitted to the existing remote unit via the second new optical line, and the first downlink optical signal is transmitted. In the uplink communication mode, the first up of the existing service frequency band received via the second new optical line includes the stage of generating the second RF communication signal based on the downlink optical signal and providing the service. The step of combining the link optical signal and the second uplink optical signal of the new service frequency band to generate at least one uplink optical coupled signal and transmitting the signal via the second existing optical line, and the at least one uplink. The step of integrating the optical coupling signals and transmitting them via the first existing optical line and the uplink optical coupling signal are separated into a first uplink optical signal and a second uplink optical signal, and the first uplink optical signal is separated. The signal is transmitted to the existing master unit via the first novel optical line, and includes a step of photoelectrically converting the second uplink optical signal to generate an uplink digital signal.

In the present invention, by using a new service equipment having an optical line integrated module using WDM technology, the new service integrated equipment is added to the existing equipment while maintaining the main optical line installed in the existing building or the like. The service can be added-on (Add-on) by adding. Since the additional new service equipment has an optical line integration module that uses WDM technology, it is possible to add new service integration equipment and provide services while maintaining the existing optical line. By newly installing an additional optical line that is shorter than the existing optical line to the distributed antenna system that was providing the existing service and combining the signal with the new service equipment, the existing service will be provided for a long time. can do. Here, since the new equipment is installed in the immediate vicinity of the existing equipment, the length of the additional optical line is very short, which simplifies the installation process and reduces the cost.

It is a block diagram which showed the distributed antenna system by a prior art. It is a block diagram which showed the example of the existing method which installed the new service equipment additionally as the new service frequency band was added. It is a block diagram which showed the structure of the frequency expansion distributed antenna system by an Example of this invention. It is a block diagram which showed the detailed structure of the additional master unit shown in FIG. It is a block diagram which showed the detailed structure of the additional remote unit shown in FIG.

Prior to explaining some embodiments of the present invention in detail, its application is not limited by the details of the composition and arrangement of the components described in the following detailed description or shown in the drawings. Must be understood. The present invention can be embodied and implemented in other embodiments and can be accomplished in a variety of ways. Also, the orientation of the device or element (eg, "front", "back", "up", "down", "top", "bottom". , "Left", "right", "lateral")), the expressions and predicates used in the present application are used solely to simplify the description of the invention and are relevant. It does not mean that the device or element of the above simply indicates that it must have a specific direction.

In addition, terms such as "first" and "second" are used in the present application and the accompanying claims for the sake of explanation, and are meant to indicate relative importance or purpose. Not intended for.

The present invention has the following features in order to achieve the above object. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to the description, the terms or words used herein and in the scope of the claim are not to be construed in a conventional or lexicographical sense, but the inventor is in order to describe his invention in the best possible way. It must be interpreted as a meaning and concept that fits the technical idea of the present invention in accordance with the principle that the concept of terms can be properly defined. Therefore, the examples described in the present specification and the configurations shown in the drawings are merely the most preferable examples of the present invention, and do not represent all the technical ideas of the present invention. It must be understood that there may be a variety of equivalents and variations in which these can be replaced at the time of filing.

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

FIG. 1 is a block diagram showing a distributed antenna system according to the prior art. FIG. 2 is a block diagram showing an existing method in which new service frequency band equipment is additionally installed by adding a new service frequency.

Referring to FIG. 1, a conventional distributed antenna system is composed of a master unit 10, a hub unit 20, a large number of remote units 30, an optical line 40, and the like in order to relay a communication signal between a base station and a user terminal. Can be done.

FIG. 2 is a block diagram showing an example of an existing method in which new service equipment is additionally installed by adding a new service frequency band. Referring to FIG. 2, for the new service frequency, the node new additional master unit 60, additional hub 70, additional remote unit 80 and additional optical line 90, additional antenna 98, and RF coaxial for said additional antenna 98. Since all cables 95 must be additionally installed, the cost increases, and it is possible to dismantle the existing building structure or the existing optical line or installation equipment for installation and re-install it. Since it occurs, the construction is troublesome and difficult.

A frequency expansion distributed antenna system according to a preferred embodiment of the present invention for solving the above-mentioned problems of the prior art will be described in detail below with reference to the accompanying drawings.

FIG. 3 is a block diagram showing a configuration of a frequency expansion distributed antenna system according to an embodiment of the present invention.

The frequency extension distributed antenna system according to a preferred embodiment of the present invention includes an existing master unit 100, an additional master unit 300, an integrated hub 400, an additional remote unit 500, and a multiplexer 600.

The existing master unit 100 converts the mobile communication signal of the existing service frequency band serviced by the first base station 850 into the first downlink optical signal converted into an optical frame, and adds the additional master unit via the first new optical line 110. Transmit to 300. The mobile communication signal in the existing service frequency band may include an RF frequency signal, an IF frequency signal or a digital signal. Further, the existing master unit 100 receives the first uplink optical signal from the additional master unit 300 via the first new optical line 110, converts it into a mobile communication signal, and transmits it to the first base station 850. To do.

The additional master unit 300 combines the first downlink optical signal and the second downlink optical signal of the new service frequency band serviced from the second base station 900, and combines the downlink optical coupling signal with the first existing optical line 200. Is transmitted via. The new service frequency band is different from the existing service frequency band.

The method of transmitting the first downlink optical signal and the second downlink optical signal via a single optical line can be presented in roughly two ways as described below. A method in which the first downlink optical signal is directly combined with the second downlink optical signal by a WDM Combiner / Splitter, and a method in which the first downlink optical signal is converted into a digital signal and combined with the second downlink optical signal in one digital frame. There is a method of combining and converting this into an optical signal (in this case, a framer / deframer function is required).

Further, the additional master unit 300 separates the uplink optical coupling signal from the integrated hub 400 into a first uplink optical signal and a second uplink optical signal, and separates the first uplink optical signal into the first uplink optical signal. It is transmitted to the existing master unit 100 via the new optical line 110, and the second uplink optical signal is photoelectrically converted to generate an uplink digital signal.

The additional master unit 300 includes a digital signal conversion unit 310, a first digital processing unit 320, a first lightning / photoelectric conversion unit 330, and a first WDM 340.

The digital signal conversion unit 310 receives an RF signal, an IF signal, or a digitally converted signal as a mobile communication signal of the new service frequency band from the second base station 900, and the RF signal or the IF signal is down. It is converted into a link digital signal and output, and the digitally converted downlink signal is output to the first digital processing unit 320 as it is. Further, the digital signal conversion unit 310 transmits the uplink digital signal to the second base station 900, or converts it into an RF signal or an IF signal and transmits the uplink digital signal to the second base station 900.

The first digital processing unit 320 generates a digital frame capable of optical transmission of the downlink digital signal through a processing process such as filtering and coding. Further, the first lightning / photoelectric conversion unit 330 performs lightning conversion of the generated digital frame to generate the second downlink optical signal. The first lightning / photoelectric conversion unit 330 photoelectrically converts the second uplink optical signal from the first WDM340 to generate an uplink digital signal.

The first WDM 340 is an integrated type of the optical coupling signal obtained by combining the first downlink optical signal and the second downlink optical signal from the existing master unit 100 via the first existing optical line 200. It transmits to the hub 400. Further, the first WDM 340 separates the uplink optical coupling signal from the integrated hub 400 into a first uplink optical signal and a second uplink optical signal, and the first uplink optical signal is the first novel ray. It is transmitted to the existing master unit 100 via the path 110, and the second uplink optical signal is output to the first lightning / photoelectric conversion unit 330.

The integrated hub 400 distributes and transmits the optical coupling signal via the second existing optical line 210. The integrated hub 400 also integrates at least one uplink optical coupling signal from at least one additional remote unit 500 and transmits it to the additional master unit 300 via the first existing optical line 200.

The additional remote unit 500 receives the downlink optical coupling signal from the integrated hub 400 and separates it into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is the first downlink optical signal. It is transmitted to the existing remote unit 700 via the second new optical line 512, generates a second RF communication signal based on the second downlink optical signal, and provides a service via the multiplexer 600 and the antenna 800. On the other hand, the existing remote unit 700 generates a first RF communication signal based on the first downlink optical signal and transmits it to the multiplexer 600.

The additional remote unit 500 generates a second uplink optical signal based on the second uplink RF communication signal from the multiplexer 600, and the first uplink optical signal and the second uplink optical signal from the existing remote unit 700. The uplink optical coupling signal is coupled to generate an uplink optical coupling signal, which is transmitted to the integrated hub 400 via the second existing optical line 210.

The additional remote unit 500 includes a second WDM 510, a second lightning / photoelectric conversion unit 520, a second digital processing unit 530, and an RF conversion unit 540.

The second WDM 510 separates the downlink optical coupling signal transmitted via the second existing optical line 210 into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal. Is transmitted to the existing remote unit 700 via the second new optical line 512.

Further, the second WDM 510 combines the first uplink optical signal from the existing remote unit 700 and the second uplink optical signal from the second lightning / photoelectric conversion unit 520 to generate an uplink optical coupling signal. , Transmit to the integrated hub 400 via the second existing optical line 210.

The second lightning / photoelectric conversion unit 520 performs optical / electric conversion of the separated second downlink optical signal to generate a downlink digital signal. Further, the second lightning / photoelectric conversion unit 520 converts the uplink digital signal from the second digital processing unit 530 into electrical / optical conversion and outputs a second uplink optical signal.

The second digital processing unit 530 processes the downlink digital signal. Further, the second digital processing unit 530 processes the second uplink RF signal from the multiplexer 600 to generate an uplink digital signal. The RF conversion unit 540 RF-converts the processed downlink digital signal to generate the second RF communication signal, and provides the second RF communication signal to the multiplexer 600.

The multiplexer 600 frequency-multiplexes the first RF communication signal from the existing remote unit 700 and the second RF communication signal from the additional remote unit 500, and service coverage of the frequency-multiplexed RF signal via the antenna 800. Transmit to the area. Further, the multiplexer 600 frequency demultiplexes the RF signal received via the antenna 800, and converts the first and second uplink RF communication signals having the existing service frequency band and the new service frequency band into the existing remote units, respectively. Provided to 700 and additional remote unit 500. The existing remote unit 700 generates a first uplink optical signal based on the first uplink RF communication signal from the multiplexer 600 and provides the additional remote unit 500 via a second new optical line 512. To do.

100 Existing master unit 110 1st new optical line 200 1st existing optical line 210 2nd existing optical line 300 Additional master unit 310 Digital signal conversion unit 320 1st digital processing unit 330 1st lightning / photoelectric conversion unit 340 1st WDM
400 Integrated Hub 500 Additional Remote Unit 510 2nd WDM
512 2nd new optical line 520 2nd lightning / photoelectric conversion unit 530 2nd digital processing unit 540 RF conversion unit 600 multiplexer 700 Existing remote unit 800 antenna 850 1st base station 900 2nd base station

Claims (10)

A downlink optical coupling signal that combines a first downlink optical signal in the existing service frequency band and a second downlink optical signal in the new service frequency band received via the first new optical line is transmitted via the first existing optical line. With an additional master unit to transmit
An integrated hub that distributes and transmits the downlink optical coupling signal via the second existing optical line,
The downlink optical coupling signal from the integrated hub is received and separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is passed through a second new optical line. Includes an additional remote unit that is transmitted to an existing remote unit to generate a second RF communication signal based on the second downlink optical signal to provide a service.
Frequency expansion distributed antenna system. The additional master unit receives an RF signal, an IF signal, or a digitally converted signal as a mobile communication signal of the new service frequency band from the second base station, and the RF signal or the IF signal is downlink. A digital signal converter that converts to a digital signal and outputs it, and outputs the digitally converted downlink signal as it is.
A first digital processing unit that processes the downlink digital signal to generate a digital frame capable of optical transmission, and
A first lightning / photoelectric conversion unit that generates the second downlink optical signal by lightning-converting the generated digital frame capable of optical transmission.
A first WDM that transmits the optical coupling signal obtained by coupling the first downlink optical signal and the second downlink optical signal to the integrated hub via the first existing optical line is included.
The additional remote unit
The downlink optical coupling signal transmitted via the second existing optical line is separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is the second new. The second WDM transmitted to the existing remote unit via the optical line,
A second lightning / photoelectric conversion unit that photoelectrically converts the separated second downlink optical signal to generate a downlink digital signal, and
A second digital processing unit that processes the downlink digital signal,
It includes an RF conversion unit that RF-converts the processed downlink digital signal to generate the second RF communication signal.
The frequency expansion distributed antenna system according to claim 1. An existing mobile communication signal in the existing service frequency band serviced by the first base station is converted into the first downlink optical signal converted into an optical frame and transmitted to the additional master unit via the first new optical line. With the master unit
An existing remote unit that generates and transmits a first RF communication signal based on the first downlink optical signal, and
A multiplex that acquires the frequency-multiplexed RF signal by frequency-multiplexing the first RF communication signal from the existing remote unit and the second RF communication signal from the additional remote unit, and transmits the frequency-multiplexed RF signal to the service coverage region via an antenna. Including more with Xar,
The frequency expansion distributed antenna system according to claim 1. The first uplink optical signal in the existing service frequency band and the second uplink optical signal in the new service frequency band received via the second new optical line are combined to generate at least one uplink optical coupled signal. With at least one additional remote unit transmitting over the second existing optical line,
An integrated hub that integrates and transmits the at least one uplink optical coupled signal from the at least one additional remote unit over the first existing optical line.
The uplink optical coupling signal from the integrated hub is separated into a first uplink optical signal and a second uplink optical signal, and the first uplink optical signal is sent to an existing master unit via a first new optical line. Includes an additional master unit that transmits and photoelectrically converts the second uplink optical signal to generate an uplink digital signal.
Frequency expansion distributed antenna system. The additional remote unit
A second digital processing unit that processes the second uplink RF signal to generate the uplink digital signal, and
A second lightning / photoelectric conversion unit that converts the uplink digital signal into lightning and outputs the second uplink light signal.
The first uplink optical signal from the existing remote unit and the second uplink optical signal are combined to generate an uplink optical coupling signal, which is transmitted to the integrated hub via the second existing optical line. Including 2WDM
The additional master unit
The uplink optical coupling signal from the integrated hub is separated into a first uplink optical signal and a second uplink optical signal, and the first uplink optical signal is the existing master via the first novel optical line. The first WDM that transmits to the unit and outputs the second uplink optical signal,
A first lightning / photoelectric conversion unit that photoelectrically converts the second uplink optical signal from the first WDM to generate the uplink digital signal, and
It includes a digital signal conversion unit that transmits the uplink digital signal to the second base station or converts it into an RF signal or an IF signal and transmits it to the second base station.
The frequency expansion distributed antenna system according to claim 4. A multiplexer that demultiplexes the frequency of the RF signal received via the antenna and outputs the first and second uplink RF communication signals, respectively.
An existing remote unit that generates the first uplink optical signal based on the first uplink RF communication signal and provides the additional remote unit via the second new optical line.
Further including the existing master unit that receives the first uplink optical signal from the additional master unit via the first new optical line, converts it into a mobile communication signal, and transmits it to the first base station.
The frequency expansion distributed antenna system according to claim 4. A downlink optical coupling signal that combines a first downlink optical signal in the existing service frequency band and a second downlink optical signal in the new service frequency band received via the first new optical line is transmitted via the first existing optical line. The input uplink optical coupling signal is separated into a first uplink optical signal and a second uplink optical signal, and the first uplink optical signal transmits a first new optical line to an existing master unit. An additional master unit that photoelectrically converts the second uplink optical signal to generate an uplink digital signal,
An integrated hub that distributes and transmits the downlink optical coupling signal via the second existing optical line, integrates at least one uplink optical coupling signal, and transmits the downlink optical coupling signal via the first existing optical line.
The downlink optical coupling signal from the integrated hub is received and separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is passed through a second new optical line. The first of the existing service frequency bands received via the second new optical line, which is transmitted to the existing remote unit to generate a second RF communication signal based on the second downlink optical signal to provide a service. Includes an additional remote unit that combines an uplink optical signal and a second uplink optical signal in the new service frequency band to generate at least one uplink optical coupled signal and transmits it over the second existing optical line.
Frequency expansion distributed antenna system. A downlink optical coupling signal that combines a first downlink optical signal in the existing service frequency band and a second downlink optical signal in the new service frequency band received via the first new optical line is transmitted via the first existing optical line. And the stage of transmission
The stage of distributed transmission of the downlink optical coupling signal via the second existing optical line, and
The downlink optical coupling signal is received and separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is transmitted to the existing remote unit via the second new optical line. A step of generating a second RF communication signal based on the second downlink optical signal to provide a service is included.
Frequency expansion method. The first uplink optical signal in the existing service frequency band and the second uplink optical signal in the new service frequency band received via the second new optical line are combined to generate at least one uplink optical coupled signal. The stage of transmission via the second existing optical line and
The stage of integrating the at least one uplink optical coupling signal and transmitting it via the first existing optical line, and
The uplink optical coupling signal is separated into a first uplink optical signal and a second uplink optical signal, the first uplink optical signal is transmitted to an existing master unit via a first novel optical line, and the second uplink optical signal is transmitted. Including the step of photoelectric conversion of an uplink optical signal to generate an uplink digital signal,
Frequency expansion method. In the downlink communication mode, the downlink optical coupling signal obtained by combining the first downlink optical signal in the existing service frequency band and the second downlink optical signal in the new service frequency band received via the first new optical line is used. 1 The stage of transmission via the existing optical line and
The stage of distributed transmission of the downlink optical coupling signal via the second existing optical line, and
The downlink optical coupling signal is received and separated into the first downlink optical signal and the second downlink optical signal, and the first downlink optical signal is transmitted to the existing remote unit via the second new optical line. A step of generating a second RF communication signal based on the second downlink optical signal to provide a service is included.
In the uplink communication mode, at least one uplink optical signal is combined with the first uplink optical signal in the existing service frequency band and the second uplink optical signal in the new service frequency band received via the second new optical line. The stage of generating a coupled signal and transmitting it via the second existing optical line,
The stage of integrating the at least one uplink optical coupling signal and transmitting it via the first existing optical line, and
The uplink optical coupling signal is separated into a first uplink optical signal and a second uplink optical signal, the first uplink optical signal is transmitted to an existing master unit via a first novel optical line, and the second uplink optical signal is transmitted. Including the step of photoelectrically converting an uplink optical signal to generate an uplink digital signal,
Frequency expansion method.