KR20100003108A - Rf femto-cell system using ftth network - Google Patents

Abstract

PURPOSE: An RF femtocell system using an FTTH network is provided to use an existing FTTH network, thereby maximizing the efficiency of optical fiber. CONSTITUTION: A master unit(60) performs electric to optic conversion after the TDM(Time Division Multiplexing) of a first RF(Radio Frequency) signal. The master unit performs demultiplexing after the optic to electric conversion of a second RF signal. A first signal coupling/splitting unit(20) couples the first RF signal with the first FTTH(Fiber To The Home) signal of an OLT(Optical Line Terminal)(10). The first signal coupling/splitting unit performs the downlink transmission of a first optical signal through optical fiber. The first signal coupling/splitting unit splits the second RF signal and a second FTTH signal from a second optical signal. A second signal coupling/splitting unit(30) distributes identically the first optical signal to each sharing unit(70-1~70-n) according to a port.

Description

RF FEMTO-CELL SYSTEM USING FTTH NETWORK}

The present invention relates to a radio frequency (Femto-cell) system using an FTTH (Fiber To The Home) network. In particular, the FTTH network is used to carry a single optical fiber without affecting existing high-speed Internet services. The present invention relates to a remote RF femtocell system capable of providing Internet (WiBro) services in the home.

Recently, due to the rapid development of communication, computer network, and semiconductor technology, various services using wireless communication networks are being provided, and demands of consumers are increasing day by day, and the global market for wireless internet services is exploding. It is a trend. Accordingly, a service provided by a mobile communication system using a wireless communication network is developing not only a voice service but also a multimedia communication service for transmitting various data.

Thus, wireless data services of Code Division Multiple Access (CDMA) 2000 1X, 3X, EV-DO, WCDMA, WLAN are currently commercialized. However, such a conventional mobile communication system has a high usage fee and low portability. In addition, wireless local area network (WLAN) technology has limitations in providing public services due to problems such as radio wave interference and a narrow coverage area. Therefore, WiBro (Wireless Broadband Internet), a high-speed portable Internet service that guarantees portability and mobility and can use a high-speed wireless Internet service at a low price, has been proposed.

WiBro service is a service that can use various information and contents by accessing the Internet in indoor and outdoor stationary environment and mobile environment using various types of portable mobile communication terminals. The WiBro system is an IP (Internet Protocol) based wireless data system that uses the 2.3 GHz frequency band and provides mobility.

A configuration diagram of a transmission network for providing such a WiBro service is shown in FIG. 1. Looking at the WiBro network structure with reference to Figure 1 as follows.

Data transmitted from an access control router (ACR) connected to a telecommunications carrier's network passes through an aggregation switch located at a branch / branch to a corresponding portable subscriber station (PSS) via a radio access station (RAS). Is sent. In addition, the control station (ACR), the aggregation switch and the base station (RAS) are connected by optical fibers to maximize the efficiency and reliability of data transmission. In addition, the optical repeater (optical repeater) is connected to the base station (RAS) by the optical fiber serves to extend the service range of the base station (RAS).

In order to provide WiBro service, forward deployment facilities such as routers, switches, and RAS are required.In the case of RAS, the service should not be troubled when the place for installation is continuously leased, maintained, repaired, and managed. .

Recently, the use of mobile phones and mobile data in homes is continuously increasing, and according to this trend, small mobile communication base stations are installed in the house to provide mobile communication services to access mobile communication core networks through indoor broadband networks. A method is proposed. This small mobile communication base station is called a femto-cell.

Femto is a unit representing ^10-15 , and the femtocell has a radius of several tens of meters, which is smaller than a picocell having a cell radius of less than 100 m. The main feature and advantage of the femtocell is that, unlike the fixed mobile convergence (FMC) service based on UMA (Unlicensed Mobile Access), which requires dual-mode terminals, the current mobile phone can be used in the femtozone. . Accordingly, femtocells are expected to be able to act as a gateway for home network services in the home as well as effects such as rate cuts, coverage of mobile communication networks, and network operation costs.

In addition, due to the rapid development of optical communication technology, the optical subscriber network applying this to the subscriber network is rapidly developing. In other words, in order to accommodate the rapidly increasing amount of Internet data traffic, attempts are being actively made to convert the existing subscriber network to the FTTH method. For example, the FTTH of the WDM-PON method is economical. In addition, many studies are being conducted because there is an advantage that can fully utilize the transmission band of the optical fiber.

FTTH has been in the spotlight as the next generation subscriber network infrastructure because fiber is installed in the interval from the telephone company to the subscriber's premises to provide the subscriber with high-speed data service. For example, as of 2007, pure FTTH transmitted by fiber to the home as of 2007 is 7.8% of the total internet network, and 38% of the similar FTTH (in the case of apartments, transmitted to the underground communication room). It aims to increase the penetration rate to 92% in 2010 and 100% FTTH in 2015. Considering this increasing trend, the proper utilization of the rapidly increasing optical subscriber network will be a very useful way to reduce the CAPEX and OPEX to enable the telecommunications market to be activated and the service to be advanced.

Therefore, it is a problem of the present invention to implement a femtocell through an FTTH network. This can be achieved by, for example, transmitting WiBro data using an FTTH network among existing broadband networks installed in a building and providing a base station with access to a service by installing a micro base station in the home.

Therefore, an object of the present invention is to provide a remote RF femtocell system that can provide WiBro services in-house through a single optical fiber without using an FTTH network but affecting existing high-speed Internet service.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention which are not mentioned above can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

According to a first embodiment of the present invention for achieving the above object, in a femto-cell system, after performing time division multiplexing (TDM) on a first radio signal, all / optical conversion is transmitted and received second A master device for demultiplexing and processing a radio signal after optical / electric conversion; The first optical signal, which is pre- / optically converted, is combined with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber, and upwardly transmitted through the optical fiber. First signal combining and distributing means for separating the second wireless signal and the second FTTH signal from a second optical signal; And second signal combining and distributing means for distributing the first optical signal transmitted downward to each slave device in the same way for each port, and combining the optical signals received from each slave device to transmit the second optical signal upward. It is characterized by including.

Here, in a slave device of a femto-cell system, a first wireless signal and a first fiber to the home (FTTH) signal are separated from a first optical signal transmitted downward through an optical fiber to separate the first FTTH signal. First signal combining and distributing means for transmitting to an optical network unit (ONU) and for transmitting uplink / optically converted second wireless signal to a remote node (RN) by combining the second FTTH signal of the ONU; Optical / electric conversion means for optically / electrically converting the first radio signal separated from the first signal combining and distributing means in downlink; All-optical conversion means for all-optical conversion of the second radio signal in uplink; And a wireless communication means for reconstructing and transmitting a signal allocated to a corresponding port from the optical / electrically converted first wireless signal, and receiving the second wireless signal.

Accordingly, according to the first embodiment of the present invention, in a femto-cell system, after performing time division multiplexing (TDM) on a first radio signal, it transmits by pre / photo conversion and transmits the received second radio signal by optical. A master device for demultiplexing and / or pre-converting; The first optical signal, which is pre / optically converted, is combined with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber, and is transmitted upward through the optical fiber. First signal combining and distributing means for separating the second wireless signal and the second FTTH signal from a second optical signal; Second signal combining and distributing means for distributing the first optical signal transmitted downward to each slave device in the same way for each port, and combining the optical signal received from each slave device to transmit the second optical signal upward; And separating the first wireless signal and the first FTTH signal from the first optical signal, transferring the first FTTH signal to an optical network unit (ONU), and optically / electrically converting and transmitting the first wireless signal. At least one slave device for pre- / optical conversion of the received second radio signal and combined with the second FTTH signal of the ONU for transmission to the second signal combining and distributing means.

On the other hand, according to a second embodiment of the present invention for achieving the above object, in a femto-cell system, the wavelength of each optical signal having a different wavelength after the pre- / optical conversion of the data corresponding to each subscriber A master device for transmitting the first radio signal by division multiplexing, demultiplexing the received second radio signal, and optically / preconverting and processing each optical signal having a different wavelength; Combining the first radio signal with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber and in a second optical signal transmitted upward through the optical fiber First signal combining and distributing means for separating the second radio signal and the second FTTH signal; And distributing the first optical signal transmitted downward to each slave device in the same way for each port, and combining and distributing a second signal for uplinking the second optical signal by combining the optical signals received from each slave device. It comprises a means.

Here, in a slave device of a femto-cell system, a first wireless signal and a first fiber to the home (FTTH) signal are separated from a first optical signal transmitted downward through an optical fiber to separate the first FTTH signal. First signal combining and distributing means for transmitting to an optical network unit (ONU) and for transmitting uplink / optically converted second wireless signal to a remote node (RN) by combining the second FTTH signal of the ONU; Filtering means for filtering a signal of a wavelength assigned to a corresponding port in the first radio signal separated by the first signal combining and distributing means in downlink; And optical signal processing and wireless communication means for optically / preconverting and transmitting the signal filtered in the downlink, and receiving and transmitting the second radio signal before and after optical conversion.

On the other hand, according to a third embodiment of the present invention for achieving the above object, in a femto-cell system, after converting the data corresponding to each subscriber / optical conversion of each optical signal having a different wavelength A master device for transmitting a first radio signal by performing wavelength division multiplexing, demultiplexing the received second radio signal, and optically / preconverting and processing each optical signal having a different wavelength; Combining the first radio signal with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber and in a second optical signal transmitted upward through the optical fiber First signal combining and distributing means for separating the second radio signal and the second FTTH signal; The first FTTH signal is separated from the first optical signal transmitted downward, and the first FTTH signal is transmitted to a remote node (RN), and the multiplexed second radio signal is transmitted to the RN. Second signal combining and distributing means, in combination with a second FTTH signal, for upwardly transmitting the second optical signal through the optical fiber; And demultiplexing the first radio signal in downlink to distribute each optical signal having a different wavelength to a corresponding slave device, and multiplexing / reversing to transmit the second radio signal by multiplexing an optical signal received from each slave device. And multiplexing means.

As described above, the present invention has an effect of using a conventional FTTH network, but can build a femtocell that supplies other telecommunications (especially WiBro) services to a home through a single optical fiber without negatively affecting high-speed Internet service. .

In particular, the deployment method is simpler than the existing method of establishing a new wireless network for WiBro in-house service, and it is possible to expect a direct cost-saving effect related to the construction, maintenance, management, and repair, and by using the existing FTTH network, Maximizing the efficiency of the optical fiber and economically providing high quality wired / wireless service has the advantage of providing additional effects.

The above objects, features, and advantages will become more apparent from the following detailed description with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains may have the technical idea of the present invention. It will be easy to implement. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a diagram illustrating an embodiment of an RF femtocell system using an FTTH network according to the present invention, and time-division multiplexed (TDM) a radio signal (for example, a WiBro signal) in an FTTH network configured with TDM-PON (EPON). Shows the configuration of a remote RF femtocell system according to the method. For convenience of explanation, it will be described together with reference to FIG. 5.

The TDM-PON method refers to a method of performing data transmission / reception at a time allocated for each subscriber by time division among passive optical subscriber network implementation methods.

Fiber optic subscriber network FTTH (Fiber To The Home) refers to the fiber-optic cabling of all subscriber lines from the telephone company to the subscriber's premises in order to establish a high-speed information communication network. This is the final goal of optical communication of subscriber network for high speed communication.

In the FTTH network, an optical line terminal (OLT) 10 is an optical subscriber network component installed in a national office and connecting a backbone network and a subscriber network to each other, and serves to terminate an optical signal. Corresponding to the domestic OLT 10, the ONU 80 is installed in the subscriber premises / home.

ONU (Optical Network Unit) 80 refers to a small outdoor / indoor optical communication device installed at the center of a residential dense area.

As shown in FIG. 2, the remote RF femtocell system according to the present invention, after time division multiplexing (TDM) of a first radio signal (ie, at least one WiBro signal (eg, a WiBro signal having a wavelength of 1550 nm)). All / optical conversion (processed by all / optical conversion unit 40) and transmitted, and the received second radio signal (ie, at least one WiBro signal (eg, a WiBro signal having a wavelength of 1530 nm, etc.)) A first unit FTTH of the OLT 10 and a master unit 60 for demultiplexing and processing the converted (processed by the optical / pre-conversion unit 50) and processing the pre- / optical converted first radio signal; A first optical signal (ie, at least one WiBro signal (eg, a WiBro signal of 1550 nm wavelength, etc.) + at least one in combination with a signal (ie, at least one FTTH signal (eg, a signal of 1490 nm wavelength, etc.)). An FTTH signal (eg, a signal of 1490 nm wavelength, etc.) downwardly through the optical fiber, and a second optical signal (ie, at least one) upwardly transmitted through the optical fiber The WiBro signal (e.g., a WiBro signal with a wavelength of 1530 nm, etc.) + at least one FTTH signal (e.g., with a signal of 1310 nm wavelength, etc.) WDM coupler / splitter (especially an optical element having a function of separating and combining a signal having a wavelength greater than or equal to 1510 nm and less) 20, and each slave device having the same first optical signal transmitted downward for each port ( 70-1 to 70-n, and combines the optical signals received from each slave device 70-1 to 70-n to provide an RN (Remote Node) 30 for transmitting the second optical signal upward. Include.

Here, a plurality of WiBro signals and a plurality of FTTH signals are coupled to the first optical signal and the second optical signal.

In addition, the WDM splitter 20 may include a second optical signal (ie, at least one WiBro signal (eg, a WiBro signal having a wavelength of 1530 nm), etc.) + at least one FTTH signal (eg, a signal having a wavelength of 1310 nm) )], And transmits the second radio signal (1530 nm WiBro signal) to the master device 60 and the second FTTH signal (1310 nm FTTH signal) to the OLT 10.

At this time, the second optical signal, the RN (30) and the 'optical signal that combines the FTTH signal of ONU 1 (80-1) and the pre- / optically converted radio signal of one slave device (for example, 70-1) and A signal (second radio signal + second FTTH signal) combining optical signals of another slave device (for example, 70-2 to 70-n) is transmitted upward to the WDM splitter 20 along the optical fiber.

Therefore, each slave device 70 of the remote RF femtocell system according to the present invention, as shown in Figure 5, the first optical signal (ie, at least one WiBro signal (for example, 1550nm) transmitted downward through the optical fiber) A first wireless signal (1550 nm WiBro signal) and a first FTTH signal (1490 nm FTTH signal) from the at least one FTTH signal (e.g., a signal of 1490 nm wavelength, etc.). Is transmitted to the ONU 80, and the pre- and optically converted second wireless signal (at least one WiBro signal (eg, 1530 nm WiBro signal, etc.)) and the second FTTH signal (1310 nm FTTH signal) of the ONU 80 are transmitted. WDM coupler / splitter 51 for uplink transmission to RN 30 and an opto / electric converter for opto / electric conversion of the first radio signal separated by WDM splitter 51 in downlink ( 52), in the uplink, the pre / optical conversion unit 53 for pre / optical conversion of the second radio signal, and the pre / post conversion of the first radio signal Includes an optical signal processor and an RF module 54 for receiving the (time-division multiplexing at least one of the WiBro signal) transmitted restored after separate the signals allocated to that port, and the second radio signal.

Here, the first optical signal (i.e., at least one WiBro signal (e.g., a WiBro signal of 1550 nm wavelength, etc.) + at least one FTTH signal (e.g., signal of 1490 nm wavelength, etc.) is received by the master device 60. A signal is a combination of a first radio signal (1550 nm WiBro signal) that is pre / optically converted after time division multiplexing (TDM) and a first FTTH signal (1490 nm FTTH signal) of the OLT 10. Is transmitted downward).

In addition, the RN 30 distributes the first optical signal (1550 nm WiBro signal + 1490 nm FTTH signal) transmitted downward to each slave device 70 in the same way for each port (that is, transmitted through the WDM coupler 20). The first optical signal is equally divided into n ports], and the second optical signal (1530 nm WiBro signal + 1310 nm FTTH signal) is transmitted upward through the optical fiber by combining the optical signals received from each slave device 70.

Therefore, each slave device 70 for each port separates the first radio signal (time division multiplexed WiBro signal) and the first FTTH signal from the first optical signal transmitted through the RN 30 (in the WDM splitter 51). The first radio signal by optical / pre-conversion (performed by the optical / pre-conversion unit 52) to filter only signals assigned to each port in the time-division multiplexed signal by the optical signal processing and RF module 54 It recovers the WiBro signal (at this time, it distinguishes the signal assigned to its port based on the preamble information of the received signal). In addition, it performs the function of the existing WiBro femtocell.

Then, a method of transmitting WiBro signals in the home by time division multiplexing (TDM) using a FTTH network composed of TDM-PON (or EPON) will be described.

In the case of the downlink (downlink), the first radio signal (that is, at least one WiBro signal (eg, a WiBro signal having a wavelength of 1550 nm), etc., to be transmitted from the master device 60 of the AP to each slave device 70 in the TDM scheme. )] Is time-division multiplexed (TDM), and pre- / photo-converts the multiplexed first radio signal through the pre / optical conversion unit 40.

Thereafter, the WDM coupler 20 transmits the first radio signal to a single FTTH signal (ie, at least one FTTH signal (eg, a signal having a wavelength of 1490 nm, etc.)) to the same single fiber as the fiber to which data of the existing FTTH network is transmitted. Combine with and send.

The first optical signal thus coupled and transmitted (i.e., at least one WiBro signal (e.g., a WiBro signal of 1550nm wavelength, etc.) + at least one FTTH signal (e.g., signal of 1490nm wavelength, etc.)) is the RN 30 Power is divided by each and transmitted to the WiBro AP (slave devices 70-1 to 70-n) of each home, and the transmitted first optical signal is divided into an FTTH signal and a WiBro signal by the WDM splitter 51, The FTTH signal is transmitted to the ONU 80, and the WiBro signal is transmitted to the optical / electrical change unit 52 and optically / electrically converted.

Thereafter, the optical signal processing and RF module 54 filters only the signals allocated to the respective ports from the WiBro signal converted into the time division multiplexed electrical signal and restores the WiBro signal. At this time, based on the preamble information of the received signal to distinguish the signal assigned to its own port.

On the other hand, in the uplink (uplink), the second wireless signal (ie, at least one WiBro signal (eg, a WiBro signal having a wavelength of 1530 nm, etc.) received by the slave device 70 of the AP) is pre / optical conversion. It is pre / optical converted via section 53 and combined with the FTTH signal rising from ONU 80 at WDM coupler 51.

The combined optical signal (for example, the optical signal combining the FTTH signal of ONU 1 (80-1) of the slave device 70-1 and the pre / optically converted radio signal) is transmitted to the other slave by the RN 30. It is combined with the optical signals of the device (e.g. 70-2 through 70-n) and transmitted along a single optical fiber. That is, the RN 30 combines the optical signals received from each slave device 70-1 to 70-n to form a second optical signal (that is, at least one WiBro signal (eg, a WiBro signal having a wavelength of 1530 nm, etc.)). + At least one FTTH signal (e.g., a signal of 1310 nm wavelength, etc.) uplink through the optical fiber.

The second optical signal thus transmitted is transmitted by the WDM splitter 20 to a second wireless signal (ie, at least one WiBro signal (eg, a WiBro signal having a wavelength of 1530 nm, etc.)) and a second FTTH signal (ie, at least one signal). FTTH signal (for example, a signal of 1310 nm wavelength), and the like, and are respectively transmitted to the OLT 10 and the photoelectric conversion unit 50 of the AP. That is, the second optical signal is separated by the WDM splitter 20, and the second wireless signal (1530 nm WiBro signal) is transmitted to the master device 60, and the second FTTH signal (1310 nm FTTH signal) is transmitted to the OLT 10. Delivered. Thereafter, the WiBro signal converted by the photoelectric conversion unit 50 is demultiplexed in the master device 60 to perform data processing.

3 is a diagram illustrating another embodiment of an RF femtocell system using an FTTH network according to the present invention, a method of transmitting a wireless signal (eg, a WiBro signal) by wavelength division multiplexing (WDM) in an FTTH network composed of WDM-PON Shows the configuration of a remote RF femtocell system according to the present invention. For convenience of explanation, it will be described together with reference to FIG. 6.

WDM-PON uses WDM method that multiplexes wavelength by subscriber or service, so that many ONUs (80-1 ~ 80-n) accommodate multiple optical links in one optical fiber and economically Speaks skills to build it.

As shown in Figure 3, the remote RF femtocell system according to the present invention, after converting the data corresponding to each subscriber / optical signal of different wavelengths (for example, 1545nm wavelength WiBro signal, 1550nm wavelength The WiBro signal, ..., a WiBro signal having a wavelength of 1555 nm, etc.], and transmits the first radio signal (ie, a signal having the wavelength division multiplexed with a WiBro signal having a wavelength of 1545 nm, 1550 nm, and 1555 nm). After demultiplexing the received second radio signal (eg, a 1525 nm WiBro signal, a 1530 nm WiBro signal, ..., a 1535 nm WiBro signal, etc.), each optical signal having a different wavelength is optically / preconverted. The first optical signal by combining the first radio signal with the first FTTH signal (ie, at least one FTTH signal (eg, a signal of 1490 nm wavelength, etc.) of the OLT 10) and the first radio signal for processing. Signal [i.e., at least one WiBro signal (e.g., a WiBro signal of wavelength 1545nm, 1550nm, 1555nm Multiplexed signal) + at least one FTTH signal (e.g., a signal of 1490 nm wavelength, etc.) downlink through the optical fiber, and a second optical signal (i.e., at least one WiBro signal (e.g., , WiBro signals of 1525 nm, 1530 nm, and 1535 nm wavelength-division multiplexed signals + at least one FTTH signal (e.g., a signal of 1310 nm wavelength, etc.), and a second radio signal and a second FTTH signal (1310 nm wavelength signal). WDM coupler / splitter (particularly an optical element having a function of separating and combining a signal having a wavelength greater than or equal to 1510 nm and a signal less than 20) and a first optical signal transmitted downward in the same manner for each slave And an RN 30 for distributing to the devices 70-1 to 70-n and combining the optical signals received from each slave device 70-1 to 70-n to transmit the second optical signal upward. .

Here, a plurality of WiBro signals and a plurality of FTTH signals are coupled to the first optical signal and the second optical signal.

In addition, the WDM splitter 20 may include a second optical signal transmitted upwardly (that is, at least one WiBro signal (eg, a signal obtained by wavelength division multiplexing of a WiBro signal having a wavelength of 1525 nm, 1530 nm, and 1535 nm) + at least one FTTH signal. (For example, a signal of 1310 nm wavelength, etc.)], and transmits a second radio signal (for example, a signal in which the WiBro signal of 1525 nm, 1530 nm, or 1535 nm wavelength is multiplexed) to the master device 60, and 2 FTTH signal (1310nm FTTH signal) is transmitted to the OLT (10).

In this case, the second optical signal is different from the RN 30 in the slave device (for example, 70-1) of the FTTH signal of the ONU 80-1 and the pre- / converted wireless signal. A signal (second radio signal + second FTTH signal) combining optical signals of a slave device (for example, 70-2 to 70-n) is transmitted upward to the WDM splitter 20 along an optical fiber.

Therefore, each slave device 70 of the remote RF femtocell system according to the present invention, as shown in Figure 6, the first optical signal (ie, at least one WiBro signal (1545nm, 1550 nm, 1555 nm wavelength WiBro signal is a wavelength-division multiplexed signal + at least one FTTH signal (e.g., a signal of 1490 nm wavelength), the first radio signal (e.g., 1545 nm, 1550 nm, 1555 nm wavelength WiBro signal) The wavelength division multiplexed signal) and the first FTTH signal (for example, a signal of 1490 nm wavelength, etc.) are separated, and the first FTTH signal is transmitted to the ONU 80, and the pre / light converted second wireless signal (for example, A WiBro signal of 1525 nm wavelength, a WiBro signal of 1530 nm wavelength, ..., a WiBro signal of 1535 nm wavelength, etc.] and a second FTTH signal (at least one FTTH signal (e.g., a 1310 nm FTTH signal, etc.) of ONU 80); WDM coupler / splitter 61 for coupling and, in downlink, a first separated by WDM splitter 61 A band pass filter 62 for filtering only signals having a wavelength assigned to the corresponding port in the line signal, and optically pre-converting and transmitting a signal filtered in the downlink, and receiving and pre-converting the second radio signal. And an optical signal processing and RF module 63 for later transmission.

Here, the first optical signal (at least one WiBro signal (eg, a signal of which the WiBro signal of 1545 nm, 1550 nm, and 1555 nm wavelength is multiplexed) + at least one FTTH signal (eg, a signal of 1490 nm wavelength, etc.) is In the master device 60, the first radio signal (WDM), which is pre- / optical converted and then WDM, is a wavelength-multiplexed signal of a WiBro signal having wavelengths of 1545 nm, 1550 nm, and 1555 nm, and an OLT (10). A first FTTH signal (eg, a 1490 nm FTTH signal) is combined to be transmitted downward to the RN 30 along the optical fiber.

In addition, the RN 30 distributes the downlink transmitted first optical signal (1545nm, 1550nm, 1555nm WiBro signal + 1490nm FTTH signal) to each slave device 70 in the same way for each port (that is, WDM coupler 20). Splitting the first optical signal transmitted through the same to n ports], the second optical signal (1525nm, 1530nm, 1535nm WiBro signal + 1310nm FTTH signal) by combining the optical signal received from each slave device 70; Transmits upward through the optical fiber.

In particular, the master device 60 is composed of n WiBro baseband channel modem banks, and the optical-to-electric converter port and the baseband channel modem by the wavelength division multiplexing method are mapped one-to-one to serve in a unique wavelength band. However, the master device 60 distributes one baseband channel modem to transmit WiBro data to two or more homes through at least two optical / electric converter ports in consideration of subscriber activation in the home. In this case, a spare baseband channel modem may be additionally allocated to the requested port only when the subscriber requests data transmission, thereby effectively reducing the number of channel modems of the master device 60. In this case, if the subscriber activity is assumed to be 10% at the most busy time, a typical one-to-one mapping method requires 100 channel banks of the WiBro femtocell slave device 70, while 10 is required when applying the multi-distribution method. Operation is possible.

The allocated data is converted to an optical signal through an all-optical converter (not shown) in the master device 60 in the case of downlink, and then transmitted to the arrayed waveguide gratings (AWG) 100 for wavelength division multiplexing. do.

The data of each port is multiplexed in the AWG 100 and combined with the FTTH signal of the OLT 10 by the WDM coupler 20 and transmitted downward through a single optical fiber. Of course, in the case of uplink, the WiBro signal and the FTTH signal are separated by the WDM splitter 20, and the FTTH signal is transmitted to the OLT 10, and the WiBro signal is demultiplexed in the AWG 100 and separated into respective wavelengths. The signals are converted into electrical signals and processed through opto-electric converters (not shown in the figure) of the master device 60.

The AWG 100 performs multiplexing and demultiplexing. Typically, AWGs use nearly different wavelengths for almost all technologies. Exceptionally, there are techniques that use the same wavelength, but efforts are being made to solve the reflection problem, and the everyday reflection problem is almost technically solved. It has the disadvantage of being vulnerable to reflection. Therefore, the configuration of the AWG 100 for use of different wavelengths up / down is important. Two methods may be exemplified in the AWG 100 configuration method. First, using two AWG (100), one is fixed to the upward wavelength, the other is fixed to the downward wavelength, the second method is to use only one AWG can be used using the Cyclic AWG.

The AWG 100 is originally as cyclic as free-spectral-range (FSR). For example, if the C-band passes through 1530-1560nm, it shows cyclic characteristics such as passing through the E-band up to 1400-1450nm. In the present invention, only the wavelength of 1510nm or more is designed so as not to affect the FTTH network using the wavelengths of 1490nm and 1310nm, but the selection of the wavelength is a matter of how to design the AWG, so that the wavelength used as another service in the same transmission line It can be used selectively to avoid. Since the wavelength passes through the different bands, one band is used upward and the other band is used downward and multiplexed and demultiplexed. The design of such a cyclic AWG is more expensive than a typical AWG because accurate design is required, but it is less expensive than using two AWGs, and the use of one AWG has the advantage of reducing the volume of the device.

As such, a signal transmitted through one optical fiber is separated into a WiBro signal and an FTTH signal in the WDM splitter 61 of each slave device 70, and the downlink WiBro signal transmitted by wavelength division multiplexing is used for the bandpass filter 62. Only the signals of the wavelengths assigned to the respective ports are filtered through the optical signal processing and optical / electric conversion by the RF module 63 and transmitted. That is, each slave device 70 for each port separates the first radio signal (wavelength division multiplexed WiBro signal) and the first FTTH signal from the first optical signal transmitted through the RN 30 (WDM splitter 61). In the present invention, only the signals allocated to the respective ports are filtered out of the wavelength division multiplexed signal, filtered, restored to the WiBro signal (performed by the bandpass filter 62), and optically / electrically converted and wirelessly transmitted. In addition, each slave device 70 performs the function of an existing WiBro femtocell.

Next, a method of transmitting WiBro signals in a home using a wavelength division multiplexing (WDM) method using an FTTH network composed of WDM-PON will be described.

In the case of the downlink (downlink), data corresponding to each subscriber in the master device 60 of the WiBro femtocell (that is, at least one WiBro signal (eg, 1545 nm WiBro signal, 1550 nm WiBro signal, 1555 nm WiBro signal) Etc.) are converted into optical signals (electric / optical conversion), and then multiplexed using the AWG 100.

Thereafter, the WDM coupler 20 transmits the multiplexed optical signal (first radio signal) to the first FTTH signal (ie, at least one FTTH) of the OLT 10 on the same single optical fiber to which the TDM signal of the existing FTTH network is transmitted. Signal (for example, a signal of 1490 nm wavelength, etc.).

The first optical signal thus combined and transmitted (at least one WiBro signal (eg, a signal of which the WiBro signal of 1545 nm, 1550 nm, and 1555 nm wavelength is multiplexed) + at least one FTTH signal (eg, a signal of 1490 nm wavelength, etc.) )] Is divided into power only by the RN 30 and is transmitted to the slave device 70 of each WiBro femtocell in the home, and the transmitted first optical signal is branched into an FTTH signal and a WiBro signal by the WDM splitter 61. The FTTH signal is transmitted to the ONU 80, and the wavelength division multiplexed WiBro signal is filtered only by the signal λ _n of the wavelength allocated to each slave device 70 by the band pass filter 62. In addition, the filtered signal is subjected to optical signal processing and photoelectric conversion in the RF module 63, and then processed as a WiBro signal to perform a unique function of the existing WiBro femtocell.

On the other hand, in the uplink (uplink), the WiBro uplink signal, which is pre / optically converted by the slave device 70 of the AP, is combined by the FTTH signal rising from the ONU 80 and the WDM coupler 61 to form a single optical fiber. Is sent.

The optical signal coupled by the WDM coupler 61 as described above (for example, the optical signal obtained by combining the FTTH signal of the ONU 1 80-1 of the slave device 70-1 and the WiBro signal that has been pre- or optically converted) is RN. By 30 it is combined with the optical signals of the slave device (eg, 70-2 to 70-n) having signals of different wavelengths and transmitted along a single optical fiber. That is, the RN 30 combines the optical signals received from each slave device 70-1 to 70-n to form a second optical signal (that is, at least one WiBro signal (eg, 1525 nm, 1530 nm, or 1535 nm wavelength). The WiBro signal is a wavelength division multiplexed signal) + at least one FTTH signal (for example, a signal of 1310 nm wavelength, etc.).

The second optical signal is transmitted by the WDM splitter 20 to a second wireless signal (eg, a signal obtained by wavelength division multiplexing of a WiBro signal having a wavelength of 1525 nm, 1530 nm, and 1535 nm) and a second FTTH signal (eg, 1310 wavelength). FTTH signal), and is transmitted to the OLT 10 and the AWG 100 of the AP, respectively. That is, the second optical signal is separated by the WDM splitter 20, so that the second radio signal is transmitted to the AWG 100, and the second radio signal is transmitted to the OLT 10. Thereafter, the AWG 100 demultiplexes the second radio signal (eg, a signal obtained by splitting the wavelength of the WiBro signal having a wavelength of 1525 nm, 1530 nm, and 1535 nm) into data processing corresponding to each wavelength.

On the other hand, Figure 4 is another embodiment configuration of the RF femtocell system using the FTTH network according to the present invention, by the wavelength division multiplexing (WDM) of the radio signal (for example, WiBro signal) in the FTTH network consisting of WDM-PON It shows another configuration of the remote RF femtocell system according to the transmission method. Descriptions on the same functions as those of FIG. 3 will be omitted.

However, the configuration and location of the master station 60, the AWG 100, the WDM coupler / splitter 20 is the same, the subscriber side WDM coupler / splitter (90), It can be seen that the configuration and location of the AWG 110 is different. That is, the transmitted WiBro signal is different in that it is separated / combined through the WDM coupler / splitter 90 at the front end of the RN 30, and as shown in FIG. 6, the bandpass filter 62 is not used. The AWG 110 is characterized by performing demultiplexing (downlink) and multiplexing (uplink).

Referring to another configuration of a remote RF femtocell system according to the present invention with reference to Figure 4, after converting the data corresponding to each subscriber / optical signal of different wavelengths [for example, WiBro signal of 1545nm wavelength, 1550nm Wavelength-division multiplexed (WDM) to transmit a first radio signal (ie, a signal in which the WiBro signal of 1545nm, 1550nm, and 1555nm wavelengths is multiplexed). After demultiplexing the received second radio signal (for example, a WiBro signal of 1525 nm wavelength, a WiBro signal of 1530 nm wavelength, ..., a WiBro signal of 1535 nm wavelength, etc.), each optical signal having a different wavelength is optically transmitted / received. A master device 60 for conversion and processing, and a first radio signal combined with a first FTTH signal (i.e., at least one FTTH signal (e.g., a signal of 1490 nm wavelength, etc.) of the OLT 10) for the first Optical signals (i.e., at least one WiBro signal (e.g., WiBro scenes with wavelengths of 1545 nm, 1550 nm, and 1555 nm) Is a wavelength-division multiplexed signal) + at least one FTTH signal (e.g., a signal of 1490 nm wavelength, etc.) downlink through the optical fiber, and a second optical signal (i.e., at least one WiBro signal transmitted upwardly through the optical fiber). (E.g., a signal obtained by wavelength division multiplexing of a WiBro signal having a wavelength of 1525 nm, 1530 nm, and 1535 nm) + at least one FTTH signal (eg, a signal having a wavelength of 1310 nm, etc.) in the second radio signal and the second FTTH signal (1310 nm wavelength). WDM coupler / splitter (especially an optical element having a function of separating and combining a signal having a wavelength greater than or equal to 1510 nm and a signal less than 20) 20 and a first optical signal transmitted downward. The first FTTH signal is transmitted to the RN 30 by separating the radio signal from the first FTTH signal, and the second radio signal multiplexed by the AWG 110 is combined with the second FTTH signal of the RN 30 to form a second signal. WDM coupler / splitter for uplink transmission of optical signal through optical fiber An optical device having a function of separating and combining a signal having a wavelength greater than or equal to 1510 nm and a signal less than 90] and a first radio signal separated by the WDM splitter 90 in downlink, thereby demultiplexing AWG 110 for distributing an optical signal to a corresponding slave device 70 and multiplexing an optical signal received from each slave device 70-1 to 70-n to transmit a second wireless signal to the WDM coupler 90. It includes.

Here, a plurality of WiBro signals and a plurality of FTTH signals are coupled to the first optical signal and the second optical signal.

The first optical signal (at least one WiBro signal (eg, a signal of which the WiBro signal of 1545 nm, 1550 nm, and 1555 nm wavelength is multiplexed) + at least one FTTH signal (eg, a signal of 1490 nm wavelength) is used. In the master device 60, the first radio signal (WDM), which is pre- / optical converted and then WDM, is a wavelength-multiplexed signal of a WiBro signal having wavelengths of 1545 nm, 1550 nm, and 1555 nm, and an OLT (10). A first FTTH signal (eg, a 1490 nm FTTH signal) is combined to be transmitted downward to the RN 30 along the optical fiber.

In addition, the WDM splitter 20 may include a second optical signal transmitted upwardly (that is, at least one WiBro signal (eg, a signal obtained by wavelength division multiplexing of a WiBro signal having a wavelength of 1525 nm, 1530 nm, and 1535 nm) + at least one FTTH signal. (For example, a signal of 1310 nm wavelength)], and transmits a second radio signal (for example, a signal in which the WiBro signal of 1525 nm, 1530 nm, or 1535 nm wavelength is multiplexed) to the master device 60, The second FTTH signal (1310 nm FTTH signal) is transmitted to the OLT 10.

At this time, the second optical signal includes a second FTTH signal (for example, a 1310 nm wavelength signal, etc.) of each ONU 80-1 to 80-n raised from the RN 30 and each slave device 70-1 to 70. -n) is a signal that combines a second radio signal (e.g., a WiBro signal of 1525 nm, 1530 nm, and 1535 nm wavelength-division multiplexed signals) multiplexed by the AWG 110 after being pre / optically converted. Uplink is sent to the WDM coupler / splitter 20.

Accordingly, each slave device 70-1 to 70-n transmits an optical / electric conversion of 'signal of wavelength allocated to the corresponding port by demultiplexing of the first radio signal by AWG 110' in downlink. The second wireless signal is received and converted to all / optical light, and then upwardly transmitted to the WDM coupler 90.

Next, a method of transmitting WiBro signals in a home using a wavelength division multiplexing (WDM) method using an FTTH network composed of WDM-PON will be described.

In the case of the downlink (downlink), data corresponding to each subscriber in the master device 60 of the WiBro femtocell (that is, at least one WiBro signal (eg, 1545 nm WiBro signal, 1550 nm WiBro signal, 1555 nm WiBro signal) Etc.) to optical signals (electric / optical conversion), respectively, and then multiplexed using the AWG 100.

Thereafter, the WDM coupler 20 transmits the multiplexed optical signal (first radio signal) to the first FTTH signal (ie, at least one FTTH) of the OLT 10 on the same single optical fiber to which the TDM signal of the existing FTTH network is transmitted. Signal (for example, a signal of 1490 nm wavelength, etc.).

The first optical signal thus combined and transmitted (at least one WiBro signal (eg, a signal of which the WiBro signal of 1545 nm, 1550 nm, and 1555 nm wavelength is multiplexed) + at least one FTTH signal (eg, a signal of 1490 nm wavelength, etc.) )] Is branched by the WDM splitter 90 before reaching the RN 30 so that the FTTH signal is passed to the ONU 80 via the RN 30, and the wavelength division multiplexed WiBro signal is reversed by the AWG 110. Only the signal λ _n of the wavelength allocated to each slave device 70 is multiplexed and filtered. The filtered signal is processed as a WiBro signal after the photo / electric conversion in each slave device 70-1 to 70-n to perform a unique function of the existing WiBro femtocell.

On the other hand, in the uplink (uplink), the WiBro uplink signals pre / optically converted by the slave device 70 of each AP are multiplexed through the AWG 110 and then multiplexed with the second radio signal (ie, A second FTTH signal (at least one FTTH) that is at least one WiBro signal (e.g., a signal in which the WiBro signals of 1525 nm, 1530 nm, and 1535 nm wavelengths are multiplexed) rises from the ONU 80 and is transmitted through the RN 30; Signal (e.g., a signal of 1310NM wavelength, etc.) and the WDM coupler 90 are combined and transmitted upward to a single optical fiber.

That is, the WDM coupler 90 combines the second FTTH signal transmitted from the ONU 80 through the RN 30 and the multiplexed uplink WiBro signal through the AWG 110, thereby providing a second optical signal (that is, At least one WiBro signal (eg, a signal obtained by splitting the wavelengths of the WiBro signal of 1525 nm, 1530 nm, and 1535 nm wavelengths) + at least one FTTH signal (eg, a signal having a 1310 nm wavelength).

The second optical signal is transmitted by the WDM splitter 20 to a second wireless signal (eg, a signal obtained by wavelength division multiplexing of a WiBro signal having a wavelength of 1525 nm, 1530 nm, and 1535 nm) and a second FTTH signal (eg, 1310 wavelength). FTTH signal), and is transmitted to the OLT 10 and the AWG 100 of the AP, respectively. That is, the second optical signal is separated by the WDM splitter 20, so that the second radio signal is transmitted to the AWG 100, and the second radio signal is transmitted to the OLT 10. Thereafter, the AWG 100 demultiplexes the second radio signal (eg, a signal obtained by splitting the wavelength of the WiBro signal having a wavelength of 1525 nm, 1530 nm, and 1535 nm) into data processing corresponding to each wavelength.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

The present invention can be used in WiBro femtocells and the like.

1 is a configuration diagram of a transmission network for providing a conventional mobile Internet service,

2 is a diagram illustrating an embodiment of an RF femtocell system using an FTTH network according to the present invention;

3 is a configuration diagram of another embodiment of an RF femtocell system using an FTTH network according to the present invention;

4 is a configuration diagram of another embodiment of an RF femtocell system using an FTTH network according to the present invention;

5 is a detailed configuration diagram of the slave device of FIG. 2;

FIG. 6 is a detailed configuration diagram of the slave device of FIG. 3.

* Explanation of symbols for the main parts of the drawings

10: OLT (Optical Line Terminal) 20,90: WDM Coupler / Splitter

30: RN (Remote Node) 40: all-optical conversion part

50: optical / electric converter 60: master device

70: slave unit 80: ONU (Optical Network.Unit)

100,110: AWG (Arrayed Waveguide Grating)

Claims (36)

In femto-cell system, A master device for performing time division multiplexing (TDM) on the first radio signal and then performing pre / optoconversion and transmitting and demultiplexing and processing the received second radio signal; The first optical signal, which is pre- / optically converted, is combined with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber, and upwardly transmitted through the optical fiber. First signal combining and distributing means for separating the second wireless signal and the second FTTH signal from a second optical signal; And Second signal combining and distributing means for distributing the first optical signal transmitted downward to each slave device in the same way for each port and combining the optical signals received from each slave device to transmit the second optical signal upward Remote RF femtocell system comprising a. The method of claim 1, The first signal coupling and distribution means, Separating the second optical signal, delivering the second wireless signal to the master device, and transmitting the second FTTH signal to the OLT. The method of claim 1, The second optical signal is, The second signal combining and distributing means combines an optical signal combining an FTTH signal of an optical network unit (ONU) and a pre / optically converted radio signal of one slave device with an optical signal of another slave device. A remote RF femtocell system, characterized in that it is transmitted upward to the first signal combining and distribution means. The method according to any one of claims 1 to 3, Each slave device, The first optical signal and the first FTTH signal are separated from the first optical signal to transfer the first FTTH signal to the ONU, and the pre / optically converted second wireless signal is transmitted to the second FTTH of the ONU. Third signal combining and distributing means for combining with a signal; Optical / electric conversion means for optically / electrically converting the first radio signal separated by the third signal combining and distributing means in downlink; All-optical conversion means for all-optical conversion of the second radio signal in uplink; And Radio communication means for distinguishing the signals allocated to the corresponding ports from the optical / electric conversion first radio signal, restoring and transmitting the signals, and receiving the second radio signal Remote RF femtocell system comprising a. The method of claim 4, wherein The first signal coupling and distribution means, A remote RF femtocell system, characterized in that an optical element having a function of separating and combining signals having a wavelength greater than or equal to 1510 nm and less. The method of claim 5, The second signal coupling and distribution means, A remote RF femtocell system, wherein the first optical signal transmitted downward is divided only by power and distributed to each slave device in the same way for each port. The method of claim 6, The first and second radio signals are respectively, A remote RF femtocell system, characterized in that at least one WiBro signal. In the slave device of the femto-cell system, The first optical signal and the first fiber to the home (FTTH) signal are separated from the first optical signal transmitted downward through the optical fiber, and the first FTTH signal is transmitted to the ONU (Optical Network Unit). First signal combining and distributing means for combining a second radio signal with a second FTTH signal of the ONU and transmitting the second radio signal to a remote node (RN); Optical / electric conversion means for optically / electrically converting the first radio signal separated from the first signal combining and distributing means in downlink; All-optical conversion means for all-optical conversion of the second radio signal in uplink; And Radio communication means for distinguishing the signals allocated to the corresponding ports from the optical / electric conversion first radio signal, restoring and transmitting the signals, and receiving the second radio signal Slave device of a remote RF femtocell system comprising a. The method of claim 8, The first optical signal is, A signal in which the first radio signal, which is pre / optically converted after time division multiplexing (TDM) and the first FTTH signal of an optical line terminal (OLT), is combined in the master device, is downward along the optical fiber to the RN. Slave device of a remote RF femtocell system, characterized in that transmitted. The method of claim 9, The RN is, A remote RF femtocell, wherein the first optical signal transmitted downward is distributed to each slave device in the same way for each port, and the second optical signal is transmitted upward through the optical fiber by combining the optical signals received from each slave device. Slave device in the system. The method of claim 10, After the time-division multiplexing (TDM) of the first radio signal, it is transmitted by pre / optical conversion, and after the optical / pre conversion of the second radio signal separated from 'the second optical signal transmitted upward through the optical fiber'. The master device for demultiplexing and processing; And The first optical signal, which is pre / optically converted, is combined with the first FTTH signal of the OLT to transmit the first optical signal downward through the optical fiber, and the second wireless signal and the second optical signal are converted from the second optical signal. Second signal combining and distributing means for separating the two FTTH signals The slave device of the remote RF femtocell system further comprising. The method of claim 11, The second signal coupling and distribution means, A slave device of a remote RF femtocell system, characterized in that an optical element having a function of separating and combining signals having a wavelength greater than or equal to 1510 nm and less. The method according to any one of claims 8 to 12, The first and second radio signals are respectively, Slave device of the remote RF femtocell system, characterized in that at least one WiBro signal. In femto-cell system, A master device for performing time division multiplexing (TDM) on the first radio signal and then performing pre / optoconversion and transmitting and demultiplexing and processing the received second radio signal; The first optical signal, which is pre- / optically converted, is combined with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber, and upwardly transmitted through the optical fiber. First signal combining and distributing means for separating the second wireless signal and the second FTTH signal from a second optical signal; Second signal combining and distributing means for distributing the first optical signal transmitted downward to each slave device in the same way for each port, and combining the optical signal received from each slave device to transmit the second optical signal upward; And The first optical signal and the first FTTH signal are separated from the first optical signal to transmit the first FTTH signal to an optical network unit (ONU), and optically / electrically convert and transmit the first wireless signal. At least one slave device for transmitting the second radio signal to the second signal combining and distributing means after combining the second wireless signal with the second FTTH signal of the ONU Remote RF femtocell system comprising a. The method of claim 14, The first signal coupling and distribution means, Separating the second optical signal, transferring the second wireless signal to the master device, and transmitting the second FTTH signal to the OLT, and separating and combining the signal having a wavelength greater than or equal to 1510 nm and less. Remote RF femtocell system, characterized in that having. The method of claim 15, The first and second radio signals are respectively, A remote RF femtocell system, characterized in that at least one WiBro signal. In femto-cell system, After converting the data corresponding to each subscriber, the first radio signal is transmitted by wavelength division multiplexing each optical signal having a different wavelength, and after demultiplexing the received second radio signal, each optical signal having a different wavelength is used. A master device for optically / electrically converting and processing signals; Combining the first radio signal with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber and in a second optical signal transmitted upward through the optical fiber First signal combining and distributing means for separating the second radio signal and the second FTTH signal; And Second signal combining and distributing means for distributing the first optical signal transmitted downward to each slave device in the same way for each port and combining the optical signals received from each slave device to transmit the second optical signal upward Remote RF femtocell system comprising a. The method of claim 17, The second optical signal is, The second signal combining and distributing means combines an optical signal combining an FTTH signal of an optical network unit (ONU) and a pre / optically converted radio signal of one slave device with an optical signal of another slave device. A remote RF femtocell system, characterized in that it is transmitted upward to the first signal combining and distribution means. The method of claim 18, The second signal coupling and distribution means, A remote RF femtocell system, wherein the first optical signal transmitted downward is divided only by power and distributed to each slave device in the same way for each port. The method of claim 19, Each slave device, The first optical signal and the first FTTH signal are separated from the first optical signal to transfer the first FTTH signal to the ONU, and the pre / optically converted second wireless signal is transmitted to the second FTTH of the ONU. Third signal combining and distributing means for combining with a signal; Filtering means for filtering a signal of a wavelength assigned to a corresponding port in the first radio signal separated by the third signal combining and distributing means in downlink; And Optical signal processing and wireless communication means for optically and pre-converting and transmitting the filtered signal in downlink, and receiving and transmitting the second radio signal before and after optical conversion. Remote RF femtocell system comprising a. In femto-cell system, After converting the data corresponding to each subscriber, the first radio signal is transmitted by wavelength division multiplexing each optical signal having a different wavelength, and after demultiplexing the received second radio signal, each optical signal having a different wavelength is used. A master device for optically / electrically converting and processing signals; Combining the first radio signal with a first fiber to the home (FTTH) signal of an optical line terminal (OLT) to transmit a first optical signal downward through an optical fiber and in a second optical signal transmitted upward through the optical fiber First signal combining and distributing means for separating the second radio signal and the second FTTH signal; The first FTTH signal is separated from the first optical signal transmitted downward, and the first FTTH signal is transmitted to a remote node (RN), and the multiplexed second radio signal is transmitted to the RN. Second signal combining and distributing means, in combination with a second FTTH signal, for upwardly transmitting the second optical signal through the optical fiber; And Multiplexing / demultiplexing by demultiplexing the first radio signal in downlink to distribute each optical signal having a different wavelength to the corresponding slave device, and multiplexing the optical signal received from each slave device to transmit the second radio signal Way Remote RF femtocell system comprising a. The method of claim 21, The second optical signal is, A signal obtained by combining the second FTTH signal of each ONU (Optical Network Unit) raised from the RN with the second radio signal pre- and optically converted by each slave device, and combining the first signal along the optical fiber; Remote RF femtocell system, characterized in that the transmission uplink to the distribution means. The method of claim 22, Each slave device, Remote RF femtocell system, characterized in that the downlink 'demultiplexed signal of the wavelength assigned to the corresponding port' by optical / pre-conversion to transmit, and receiving and transmitting the second radio signal up to / after optical conversion . The method of claim 21, The second signal coupling and distribution means, A remote RF femtocell system, characterized in that an optical element having a function of separating and combining signals having a wavelength greater than or equal to 1510 nm and less. The method according to any one of claims 17 to 24, The first signal coupling and distribution means, Separating the second optical signal, delivering the second wireless signal to the master device, and transmitting the second FTTH signal to the OLT. The method of claim 25, The first signal coupling and distribution means, A remote RF femtocell system, characterized in that an optical element having a function of separating and combining signals having a wavelength greater than or equal to 1510 nm and less. The method of claim 26, The first and second radio signals are respectively, A remote RF femtocell system, characterized in that at least one WiBro signal. The method of claim 27, The master device, A remote RF femtocell system comprising n WiBro baseband channel modem banks, wherein an optical / to-electric converter port and a baseband channel modem by a wavelength division multiplexing method are mapped in a one-to-one manner and each serve a unique wavelength band. The method of claim 27, The master device, Considering the subscriber's activity in the home, one baseband channel modem has a function of distributing WiBro data to two or more homes through at least two optical / electric converter ports so that the subscriber's request for data transmission can be A remote RF femtocell system, further comprising allocating a spare baseband channel modem to the requested port, if any. The method of claim 27, The master device, A remote RF femtocell system using multiple arrayed waveguide gratings (AWG) to fix one uplink wavelength and the other downlink wavelength to perform multiplexing and demultiplexing. In the slave device of the femto-cell system, The first optical signal and the first fiber to the home (FTTH) signal are separated from the first optical signal transmitted downward through the optical fiber, and the first FTTH signal is transmitted to the ONU (Optical Network Unit). First signal combining and distributing means for combining a second radio signal with a second FTTH signal of the ONU and transmitting the second radio signal to a remote node (RN); Filtering means for filtering a signal of a wavelength assigned to a corresponding port in the first radio signal separated by the first signal combining and distributing means in downlink; And Optical signal processing and wireless communication means for optically and pre-converting and transmitting the filtered signal in downlink, and receiving and transmitting the second radio signal before and after optical conversion. Slave device of a remote RF femtocell system comprising a. The method of claim 31, wherein The first optical signal is, The first device is a signal in which the first radio signal obtained by performing wavelength division multiplexing on each optical signal having a different wavelength after converting data corresponding to each subscriber by the master device and the first FTTH signal of the OLT, Slave device of the remote RF femtocell system, characterized in that the downlink transmission along the optical fiber to the RN. 33. The method of claim 32, The RN is, A remote RF femtocell, wherein the first optical signal transmitted downward is distributed to each slave device in the same way for each port, and the second optical signal is transmitted upward through the optical fiber by combining the optical signals received from each slave device. Slave device in the system. The method of claim 33, wherein After converting the data corresponding to each subscriber, the first radio signal is transmitted by wavelength division multiplexing each optical signal having a different wavelength, and after demultiplexing the received second radio signal, each having a different wavelength A master device for optically / optically converting and processing an optical signal of the optical signal; And The first optical signal is coupled with the first fiber to the home (FTTH) signal of the optical line terminal (OLT) to transmit the first optical signal downward through the optical fiber, and the optical signal is upwardly transmitted through the optical fiber. Second signal combining and distributing means for separating the second wireless signal from the second FTTH in a second optical signal The slave device of the remote RF femtocell system further comprising. The method of claim 34, wherein The second signal coupling and distribution means, A slave device of a remote RF femtocell system, characterized in that an optical element having a function of separating and combining signals having a wavelength greater than or equal to 1510 nm and less. 36. The method of any of claims 31-35, The first and second radio signals are respectively, Slave device of the remote RF femtocell system, characterized in that at least one WiBro signal.

Images