KR20170107809A - Method and apparatus for controling mobile front-haul based on radio over fiber - Google Patents

Abstract

Disclosed are a radio over fiber (RoF) based digital signal processing matching apparatus, a main radio signal processing apparatus, and a control method thereof. The method for controlling a radio over fiber (RoF) based digital signal processing matching apparatus comprises the steps of: receiving a management control frame from a local management terminal; performing a control operation based on the management control frame; and reporting the performance result to the local management terminal.

Description

TECHNICAL FIELD [0001] The present invention relates to a mobile front-hole control method and apparatus based on RoF,

The following embodiments relate to a method and apparatus for controlling a mobile front hole based on a RoF (Radio over Fiber) based on a C-RAN (Cloud / Centralized Radio Access Network) structure. More specifically, A digital unit interfacing unit, and a radio signal processing unit (RU-Radio Unit).

Transmission technologies applied to mobile front-haul in the field of wireless communication include CPRI (Common Public Radio Interface) and RoF (Radio over Fiber). The CPRI method corresponds to the digital transmission method, and the RoF method corresponds to the analog transmission method. In the current C-RAN architecture, the CPRI transmission method is mainly used. However, the CPRI method has a limitation in accommodating the traffic of 5G mobile communication, which requires a capacity of 10 Gbps to several Tbps in terms of capacity.

The RoF scheme is a technique of directly modulating a baseband signal corresponding to transmission data into a radio frequency band signal such as a microwave, converting the baseband signal into an optical signal, and transmitting the optical signal through the optical fiber. The RoF method combines optical communication technology that provides a wide bandwidth and wireless communication technology that provides mobility and has an advantage of transmitting a large amount of traffic at a low cost.

The RoF scheme can be classified into an RF over Fiber scheme for transmitting a baseband signal over an RF (Radio Frequency) carrier signal and an IF over Fiber scheme for transmitting an IF (Intermediate Frequency) carrier signal. Hereinafter, the IF frequency may be referred to as an intermediate frequency.

The present invention provides a method and apparatus for controlling a RoF-based digital signal processing matching device by performing a control operation based on a control signal received from a local management terminal.

The present invention provides a method and apparatus for controlling a RoF-based main wireless signal processing apparatus by performing a control operation based on a control signal included in a coupled signal received from a digital signal processing matching apparatus.

A method of controlling a digital signal processing registration device based on a RoF (Radio over Fiber) according to an embodiment includes receiving a control signal from a local management terminal, performing a control operation based on the control signal, And reporting the result of the performance to the user.

Wherein the step of performing performs the control operation in the digital signal processing matching device when the field indicating the destination included in the control signal is the digital signal processing matching device, And may transmit the result of the performance in the registration device to the local management terminal.

Wherein when the field indicating the destination included in the control signal is a radio signal processor, the performing step transmits the control signal to the radio signal processor via an intermediate frequency, And may transmit the result of the operation received from the device to the local management terminal.

Wherein the step of transmitting to the wireless signal processing device comprises the steps of mapping the frequency of the control signal to the intermediate frequency, combining the modulated control signal and the data signal, electro-optically converting the combined signal, And transmitting the electro-optically converted signal to the wireless signal processing apparatus.

Wherein the control signal is a signal for requesting a failure of the digital signal processing matching device or the wireless signal processing device, and the performing step may include checking a failure state change of the digital signal processing matching device or the wireless signal processing device at predetermined intervals, The reporting step may transmit the failure state change of the digital signal processing matching device or the wireless signal processing device to the local management terminal.

Wherein the control signal is a signal for status inquiry of the digital signal processing matching device or the wireless signal processing device and the reporting step is a step of transmitting the state of the digital signal processing matching device or the wireless signal processing device to the local management terminal have.

Wherein the control signal is a signal for setting control of the digital signal processing matching device or the wireless signal processing device and the reporting step transmits the control result of the digital signal processing matching device or the wireless signal processing device to the local management terminal .

A control method of a RoF-based main radio signal processing apparatus according to an exemplary embodiment includes receiving a coupling signal from a digital signal processing matching device, performing a control operation based on a control signal included in the coupling signal, And reporting the result of the performance to the signal processing registration device.

The receiving may receive the combined signal via an intermediate frequency, and the reporting may transmit the result of the performance to the digital signal processing matching device via the intermediate frequency.

Wherein the step of receiving comprises the steps of photo-electrically converting the combined signal and separating the control signal from the pre-photo-converted combined signal, wherein the frequency of the control signal is one that is mapped to the intermediate frequency .

Wherein the performing step comprises performing the control operation on the basis of the control signal when the field indicating the destination included in the control signal is the main radio signal processing apparatus and the field indicating the destination included in the control signal is The control signal can be discarded in the case of a sub-radio signal processing apparatus.

The control method of the RoF-based main radio signal processing apparatus may further include transmitting the control signal to the sub-radio signal processing apparatus using an intermediate frequency separator.

Wherein the step of reporting includes combining a signal including a result of performing the main wireless signal processing apparatus and a signal including a result of execution of the sub wireless signal processing apparatus by an intermediate frequency combiner, And transmitting a signal to the digital signal processing registration device via the intermediate frequency.

The reporting step may transmit the execution result to the digital signal processing matching device when the field indicating the destination included in the control signal is the main wireless signal processing device.

Wherein the control signal is a signal for requesting a failure of the main radio signal processor or the sub radio signal processor, and the performing of the checking includes checking a change in the fault state of the main radio signal processor at regular intervals, The failure state change of the main wireless signal processing apparatus can be transmitted.

Wherein the step of reporting includes the steps of sharing a fault state change with the sub radio signal processing apparatus through the fault presence / absence information signal, and, when a change in the fault state of the sub radio signal processing apparatus is confirmed, The failure state change of the wireless signal processing apparatus and the failure state change of the sub wireless signal processing apparatus may be transmitted to the digital signal processing matching apparatus.

Wherein the control signal is a signal for inquiring a state of the main radio signal processor or the sub radio signal processor, and the reporting step is a step of informing the state of the main radio signal processor or the sub- Device.

Wherein the control signal is a signal for setting control of the main radio signal processing apparatus or the sub-radio signal processing apparatus, and the reporting step is a step of transmitting the control result of the main radio signal processing apparatus or the sub- To a matching device.

A RoF-based digital signal processing matching device according to an embodiment includes a receiver for receiving a control signal from a local management terminal, a controller for performing a control operation based on the control signal, and a transmitter for reporting the result of the operation to the local management terminal . ≪ / RTI >

A RoF-based radio signal processing apparatus according to an embodiment includes a receiver for receiving a combined signal from a digital signal processing matching device, a controller for performing a control operation based on a control signal included in the combined signal, And a transmission unit reporting the result of the performance.

According to an embodiment, a RoF-based digital signal processing matching device can be controlled by performing a control operation based on a control signal received from a local management terminal.

According to an embodiment, the RoF-based main wireless signal processing apparatus can be controlled by performing a control operation based on a control signal included in the combined signal received from the digital signal processing matching apparatus.

1 is a view illustrating a structure of a RoF-based mobile front hole according to an embodiment.
2 is a view for explaining a flow of a control signal in a RoF-based mobile front hole according to an embodiment.
3 is a diagram illustrating a control signal transmission method through a RoF scheme between a DIU of a C-RAN structure and a plurality of RUs according to an exemplary embodiment.
4 is a diagram illustrating a protocol for failure monitoring for a component of a RoF-based mobile front hole according to an exemplary embodiment.
FIG. 5 is a diagram illustrating a protocol for status inquiry for a component of a RoF-based mobile front hole according to an embodiment.
6 is a diagram illustrating a protocol for setting control of a component of a RoF-based mobile front hole according to an exemplary embodiment.
FIG. 7 shows a flowchart of a control method of a RoF-based digital signal processing matching apparatus according to an embodiment.
8 is a flowchart illustrating a control method of a RoF-based main wireless signal processing apparatus according to an embodiment of the present invention.

It should be understood that the specific structural and functional descriptions below are merely illustrative of the embodiments and are not to be construed as limiting the scope of the patent application described herein. Various modifications and variations may be made thereto by those skilled in the art to which the present invention pertains. Reference throughout this specification to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment, It should be understood that references to "an embodiment" are not all referring to the same embodiment.

It is to be understood that the specific structural or functional descriptions for the embodiments disclosed herein are presented for purposes of illustrating illustrative embodiments only and that the embodiments may be embodied in various forms and are not limited to the embodiments described herein It does not.

The embodiments disclosed herein are capable of various modifications and may take various forms, so that the embodiments are illustrated in the drawings and described in detail herein. It is not intended to be exhaustive or to limit the invention to the specific forms disclosed, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the disclosure.

The terms first, second, or the like may be used to describe various elements, but the elements should not be limited by the terms. The terms are for purposes of distinguishing one element from another, for example, without departing from the scope of the present disclosure, the first element may be referred to as a second element, The component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between. Expressions that describe the relationship between components, for example, "between" and "immediately" or "directly adjacent to" should be interpreted as well.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the scope of the rights. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, the terms "comprises ", or" having ", and the like, are used to specify one or more of the features, numbers, steps, operations, elements, But do not preclude the presence or addition of steps, operations, elements, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the meaning of the context in the relevant art and, unless explicitly defined herein, are to be interpreted as ideal or overly formal Do not.

Embodiments to be described below can be applied to identify and determine the type of motion of an object included in a moving image.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention with reference to the accompanying drawings, the same components are denoted by the same reference numerals regardless of the reference numerals, and a duplicate description thereof will be omitted.

1 is a view illustrating a structure of a RoF-based mobile front hole according to an embodiment.

The mobile front hole refers to a network connecting a base band unit (BBU) and a remote radio head (RRH) at a mobile communication base station. Specifically, in the network of the C-RAN structure, a mobile front hole arranges a BBU for processing a digital signal in a base station, arranges an RRH configured with a minimum number of radio communication elements in a costly outdoors, And the optical transmission network that connects the optical transmission network. By placing the DAC and ADC components in the DU block, the RU's complexity can be reduced, resulting in cost savings, and efficiency can be improved by centralizing the DU. Here, the BBU may be referred to as a digital unit (DU) or a digital signal processing device, and the RRH may be referred to as a radio unit (RU) or a radio signal processing device.

In the C-RAN network, the RoF (Radio over Fiber) -based mobile front-hole technology transmits narrowband baseband signals for mobile communication using IF (intermediate frequency) based frequency multiplexing and cost effective direct optical modulation RU can be simplified and lowered, and DU can be reduced in cost by making it highly integrated and large capacity. Specifically, in the RoF-based mobile front-hole structure, an analog IF (Intermediate Frequency) signal is transmitted to the optical cable for connection between the DU and the RU. Hereinafter, the IF may be referred to as a center frequency.

RoF-based digital signal processing matching devices can perform control functions between DU and RU at the request of the local management terminal (LMT). Here, the control function may include failure monitoring, status inquiry and setting control of the digital signal processing matching device or RU. Hereinafter, the control operation of the digital signal processing matching device and the RU will be described in more detail by explaining each configuration of the RoF-based mobile front hole. A RoF-based digital signal processing matching device may be referred to as a digital interface unit (DIU).

The RoF based mobile front hall may include the DIU 120 and the RU 130. The DIU 120 processes a digital signal and outputs a baseband signal (I / Q = In-phase / Quadrature-phase), which is a digital signal received from the DU 140, Frequency), and then performs an electro-optical change to transmit to the RU 130 or vice versa. Where the baseband signal can be a signal containing data and can be referred to as a data signal.

The RU 130 separates the baseband signal received from the DIU 120 from the analog signal, converts the separated baseband signal into an available RF (Radio Frequency) signal, ) Or vice versa. Here, the DIU 120 and the RU 130 exchange analog signals through optical fibers. In the C-RAN architecture, there may be a plurality of RUs 130 and may be distributed outdoors.

The local management terminal 110 is a part for managing and controlling the mobile front hall and is a part for monitoring the failure of the DIU 120 or the RU 130 and the status inquiry of the DIU 120 or the RU 130 in cooperation with the control unit of the DIU 120 or the control unit of the RU 130. [ And setting control.

2 is a view for explaining a flow of a control signal in a RoF-based mobile front hole according to an embodiment.

The local management terminal 110 may control the DIU 120 or the RU 130 in conjunction with the control unit 211 of the DIU 120 or the control unit 212 of the RU 130. Specifically, the local management terminal 110 transmits a control signal for failure monitoring, status inquiry, and setting control of the DIU 120 or the RU 130 to the terminal transceiver 271 of the DIU 120, From the terminal transmission / reception unit 271.

The DIU 120 may include a terminal transceiver unit 271, a control unit 211, a modem 221, an IF distribution unit 231, an optical transceiver unit 241, and a converter 250. The control unit 211 may perform a control operation according to a control signal received from the local management terminal 110 through the terminal transceiver unit 271.

Specifically, the control unit 211 may process the control commands for the components of the DIU 120 and may manage the control commands for the components of the RU 130. The control unit 211 analyzes the control signal received from the local management terminal 110 and processes the control command included in the control signal when the destination is the DIU 120. When the destination is the RU 130, To the RU 130, a combined signal including a control signal.

The local management terminal 110 may generate a control frame for the DIU 120 or the RU 130 and transmit the control frame to the terminal transceiver 271 through the Ethernet interface in a control signal. The control unit 211 receives a control signal from the terminal transmission / reception unit 271 and can confirm a field including destination information in the control frame. If the destination is the DIU 120, the control unit 211 may process the corresponding control command and then transmit the result (response or ACK) to the local management terminal 110.

When the destination is the RU 130, the control unit 211 can transmit the control signal to the modem 221. [ The modem 221 may map the frequency of the control signal to an intermediate frequency (IF) corresponding to the downstream bandwidth. The IF distributor 231 can combine the modulated control signal with the modulated data signal received from the DU 140. The optical transceiver 241 can perform electro-optic conversion on the combined signal and transmit it to the RU 130 through the optical fiber. For example, the intermediate frequency for the downstream transmitted at this time may be 26.88 MHz.

The RU 130 may include a control unit 212, a modem 222, an IF distribution unit 232, an optical transceiver unit 242, and an RF transceiver unit 260. The control unit 212 may perform a control operation according to a control signal included in the coupling signal received from the DIU 120 through the optical transmitting / receiving unit 242.

Specifically, The optical transmitting / receiving unit 242 can perform photo-electrical conversion on the received combined signal. The IF distributor 232 can separate the data signal and the control signal from the combined signal. The modem 222 may perform frequency demodulation on the control signal. The control unit 212 may then process the control commands for the components of the RU 130 included in the control signal.

The control unit 212 may transmit the result (response or ACK) of the control command to the DIU 120. At this time, the process of generating the upstream signal may be the reverse of the process of processing the downstream signal. That is, the control unit 212 may transmit a report signal including information on the execution result to the modem 222. The modem 222 may map the report signal to an intermediate frequency for the upstream. The IF distributor 232 may combine the modulated data signal and the modulated data signal received from the RF transceiver 260 and the optical transceiver 242 may transmit the combined signal to the DIU 120. The DIU 120 may report the combined signal to the local management terminal 110.

According to another embodiment, the control unit 212 may selectively process the control command of the external terminal through the Ethernet interface.

The control unit 211 and the control unit 212 may be referred to as a main control unit. In addition, the control unit 211 may be referred to as a digital interface unit controller (DIUC), and the control unit 212 may be referred to as a remote unit controller (RUC). Modem 221 and modem 222 may include a Frequency Shift Keying (FSK) modem.

3 is a diagram illustrating a control signal transmission method through a RoF scheme between a DIU of a C-RAN structure and a plurality of RUs according to an exemplary embodiment.

The process of transferring the control signal from the DIU 120 to the RU 130 is as follows. The combined signal including the control signal for controlling the RU 130 transmitted through the DIU 120 in the local management terminal 110 is transmitted to the optical transmitting and receiving unit of the RU1 131 of the unit RUs (RU1, RU2, RU3) The RU2 132 and the RU3 133 as well as the RU1 131 through the IF separator 242 and the IF separator 310. [ As such, the downstream transmission scheme may be a broadcasting scheme.

At this time, the RU1 131, the RU2 132, and the RU3 133 can confirm the destination information included in the control signal by using the respective controllers 212, 213, and 214. The RU1 131, the RU2 132, and the RU3 133 process the control command included in the control signal only when the destination is the self, and can discard the control signal if not the self.

The process of transferring the control signal from the RU 130 to the DIU 120 is as follows. The report signals generated from the RU1 131, the RU2 132 and the RU3 133 are modulated through the respective modems 222, 223 and 224 and combined through the IF coupler 320, Lt; RTI ID = 0.0 > DIU < / RTI >

The report signal may be communicated to the local management terminal 110 via the DIU 120. That is, the upstream transmission may be unicast. However, since the RU2 132 and the RU3 133 also use the transmission path of the RU1 131, when the signals are simultaneously transmitted from the RU1 131, the RU2 132, and the RU3 133, .

The modem control signal (hereinafter, TxEn signal) may be a signal for controlling transmission / reception of the modems 221 and 222 from the outside. First, when the unit RUs 131, 132, and 133 are initialized, all the TxEn signals can be set to Disable. Thereafter, the TxEn signal can be changed from Disable to Enable only in the unit RUs 131, 132, and 133 corresponding to the destination of the control signal. Finally, transmission of the report signal including the management control frame for the response after a certain period of waiting for link-up of the modem can be started. After the end of the frame (EOF-End of Frame) indicating the end of the frame, the TxEn signal of the modems 221 and 222 is changed from Enable to Disable after waiting for a predetermined time, and the transmission can be completed. This can solve the problem of uplink signal collision to the DIU.

According to one embodiment, the unit RUs 131, 132, and 133 can periodically monitor (or poll) the request of the DIU 120 to check the status change of the predefined fault item. That is, the unit RUs 131, 132, and 133 may periodically perform failure monitoring. According to another embodiment, the unit RUs 131, 132, and 133 may monitor and report the status change of the fault item itself without an external request.

The IF combining unit 320 of the RU1 131 may notify the occurrence of a fault in each modem (or the RU1 131, the RU2 132, and the RU3 133) 222, 223, and 224, may result in collisions between the modulated signals. That is, if the unit RUs 131, 132, and 133 do not share the fault presence / absence information, the other unit RUs (for example, RU2 or RU3) during the failure reporting in one unit RU When a fault is reported, a signal collision may occur in the IF combining unit 320. [

In order to solve this problem, when the unit RUs 131, 132, and 133 report a failure occurrence by itself, the unit RUs 131, 132, and 133 may follow the following procedure. The unit RUs 131, 132, and 133 can share information through an RUx_y_RDI signal (x = transmission RU number, y = reception RU number) indicating RDI (Remote Defect Indication). If a failure of the unit RU 132 or 133 is confirmed in addition to the self 131, the unit RUs 131, 132, and 133 may be allocated to a predetermined priority (for example, in order of RU1> RU2> RU3) The fault report can be processed accordingly. After the failure report is completed, its RDI signal is deactivated so that another RU can process the failure report without collision.

4 is a diagram illustrating a protocol for failure monitoring for a component of a RoF-based mobile front hole according to an exemplary embodiment.

In steps 421 and 422, the controller 211 and the controller 212 polling the DIU 120 and the RU 130 for a fault item among the status items to be managed in a period of t _p (polling time) ) Can be performed.

According to one embodiment, while the control unit 211 and the control unit 212 periodically check the failure state change through the failure monitoring polling (for example, in the order DIU-RU1-RU2-RU3), at step 410 The terminal transmission / reception unit 271 may receive the status inquiry message from the local management terminal 110. [ Here, the state inquiry message may be a kind of control signal. In step 430, the terminal transceiver 271 receives the failure monitoring result from the controller 211 and the controller 212 and can transmit the failure monitoring result to the local management terminal 110.

According to another embodiment, if the change is confirmed without a request from the local management terminal 110, it may be reported to the local management terminal 110 at step 430.

According to another embodiment, each element DIU and RU performs a failure monitoring polling without intervention of the controller 211 or the controller 212, and may report the failure to itself to the local management terminal 110 have.

FIG. 5 is a diagram illustrating a protocol for status inquiry for a component of a RoF-based mobile front hole according to an embodiment. 5 is a diagram illustrating a process of inquiring statuses of remaining status items except for the fault item.

In step 510, the terminal transceiver 271 may receive a status inquiry message (or management control frame) for the DIU 120 from the local management terminal 110. The controller 211 may inquire the status of the DIU 120 and transmit it to the terminal transceiver 271. In step 540, the terminal transceiver 271 transmits the status of the DIU 120 to the terminal transceiver 271, To the local management terminal 110.

In step 510, the terminal transceiver 271 may receive a status inquiry message (or management control frame) for the RU 130 from the local management terminal 110. In step 520, the control unit 211 may transmit the control signal to the RU 130 through the optical fiber. Specifically, the control unit 211 can transmit a control signal to the modem 221. [ The modem 221 may map the frequency of the control signal to an intermediate frequency (IF) corresponding to the downstream bandwidth. The IF distributor 231 can combine the modulated control signal with the modulated data signal received from the DU 140. The optical transceiver 241 can perform electro-optic conversion on the combined signal and transmit it to the RU 130 through the optical fiber.

 In step 530, the RU 130 may send a report signal for the status inquiry to the control unit 211. Specifically, the control unit 212 may inquire the status of the RU 130, and then transmit a report signal including information on the result of the inquiry to the modem 222. The modem 222 may map the report signal to an intermediate frequency for the upstream. The IF distributor 232 may combine the modulated data signal and the modulated data signal received from the RF transceiver 260 and the optical transceiver 242 may transmit the combined signal to the DIU 120.

In step 540, the control unit 211 of the DIU 120 may report the combined signal to the local management terminal 110.

The local management terminal 110 can process a command failure if there is no response during the wait time t _w after transmitting the status inquiry command.

6 is a diagram illustrating a protocol for setting control of a component of a RoF-based mobile front hole according to an exemplary embodiment.

In step 610, the terminal transceiver 271 may receive a control request message (or management control frame) for the DIU 120 from the local management terminal 110. Here, the control request message may mean a control signal for setting control. In step 620 and step 630, the controller 211 controls the DIU 120 and transmits the DIU 120 to the terminal transceiver 271. In step 540, the terminal transceiver 271 performs (ACK-Success or Fail) to the local management terminal 110. [0064]

In step 610, the terminal transceiver 271 may receive a control request message (or management control frame) for the RU 130 from the local management terminal 110. In step 620, the control unit 211 may transmit the control signal to the RU 130 through the optical fiber. Specifically, the control unit 211 can transmit a control signal to the modem 221. [ The modem 221 may map the frequency of the control signal to an intermediate frequency (IF) corresponding to the downstream bandwidth. The IF distributor 231 can combine the modulated control signal with the modulated data signal received from the DU 140. The optical transceiver 241 can perform electro-optic conversion on the combined signal and transmit it to the RU 130 through the optical fiber.

 After the setting control is performed, in step 630, the RU 130 may send a report signal for the setting control to the control unit 211. [ The control unit 212 may transmit a report signal including information on a result of performing the setting control of the RU 130 to the modem 222. [ The modem 222 may map the report signal to an intermediate frequency for the upstream. The IF distributor 232 may combine the modulated data signal and the modulated data signal received from the RF transceiver 260 and the optical transceiver 242 may transmit the combined signal to the DIU 120.

In step 640, the controller 211 of the DIU 120 may report the combined signal to the local management terminal 110 (ACK-Success or Fail).

The local management terminal 110 can process the command failure if there is no response during the waiting time t _w after the transmission of the setting control request message.

FIG. 7 shows a flowchart of a control method of a RoF-based digital signal processing matching apparatus according to an embodiment.

In step 710, the terminal transceiver 271 of FIG. 2 may receive a control signal from the local management terminal.

In step 720, the controller 211 of FIG. 2 may perform a control operation based on the control signal. According to one embodiment, when the field indicating the destination included in the control signal is a digital signal processing matching device, the control unit 211 can perform a control operation in the digital signal processing matching device. The digital signal processing registration device may correspond to the DIU 120 of FIG.

According to another embodiment, when the field indicating the destination included in the control signal is a wireless signal processing device, the control unit 211 uses the optical transmitting / receiving unit 241 of FIG. 2 to transmit the control signal to the wireless signal The control signal can be transmitted to the processing apparatus. Specifically, the modem 221 can map the frequency of the control signal to the intermediate frequency. The IF distributor 231 of FIG. 2 can combine the modulated control signal and the data signal. The optical transmitting / receiving unit 241 The combined signal can be electro-optically converted and transmitted to the wireless signal processing device.

According to one embodiment, in the case where the control signal is for a trouble-shooting inquiry of the digital signal processing matching device or the wireless signal processing device, the control unit 211 or the control unit 212, respectively, It is possible to confirm the change of the failure state of the processing apparatus.

In step 730, the terminal transceiver 271 of FIG. 2 may report the results of the operation to the local management terminal. According to one embodiment, when the field indicating the destination included in the control signal is a digital signal processing registration device, the terminal transceiver 271 can transmit the result of the operation in the digital signal processing registration device to the local management terminal .

According to another embodiment, when the field indicating the destination included in the control signal is a digital signal processing matching device, the terminal transceiver 271 can transmit the result of the operation received from the wireless signal processing device to the local management terminal.

According to one embodiment, in the case where the control signal is a signal for requesting failure of the digital signal processing matching device or the wireless signal processing device and the terminal transmitting / receiving portion 271 receives the failure inquiry message from the local management terminal 110, The control unit 211 or the control unit 212 may transmit the failure state change of the digital signal processing matching device or the wireless signal processing device to the local management terminal 110. [

According to another embodiment, when the control signal is a signal for status inquiry of the digital signal processing matching device or the wireless signal processing device and the terminal transceiver 271 receives the status inquiry message from the local management terminal 110, The control unit 211 or the control unit 212 may transmit the status inquiry result of the digital signal processing matching device or the wireless signal processing device to the local management terminal 110.

According to another embodiment, when the control signal is a signal for setting control of the digital signal processing matching device or the wireless signal processing device and the terminal transmitting / receiving portion 271 receives the control request message from the local management terminal 110, The control unit 211 or the control unit 212 may transmit the setting control result of the digital signal processing matching device or the wireless signal processing device to the local management terminal 110. [

FIG. 8 shows a flowchart of a control method of a RoF-based main radio signal processing apparatus according to an embodiment.

The optical transceiver 242 of FIG. 2 can receive the coupling signal from the digital signal processing matching device. At this time, the optical transceiver 242 can receive the coupling signal from the digital signal processing matching device through the intermediate frequency. Specifically, the optical transmitting / receiving unit 242 can perform photo-electrical conversion of the coupled signal. The IF distributor 232 of FIG. 2 may separate the control signal from the pre-converted signal. The frequency of the control signal may be mapped to an intermediate frequency. The main radio signal processing apparatus may correspond to the unit RU 131 of FIG. 3, and the sub-radio signal processing apparatus may correspond to the unit RU 132 or 133 of FIG.

The control unit 212 may perform a control operation based on the control signal included in the combined signal. The control unit 212 performs a control operation based on the control signal when the field indicating the destination included in the control signal is the main radio signal processing apparatus and outputs a field indicating the destination included in the control signal to the sub- The IF distributor 232 may transmit the control signal to the sub-radio signal processor using the intermediate frequency separator and discard the control signal.

The optical transceiver 242 may report the result of the operation to the digital signal processing matching device. At this time, the optical transmitting / receiving unit 242 can report the result of the operation to the digital signal processing matching device through the intermediate frequency. The IF distributor 232 may combine a signal including a result of the main radio signal processor and a signal including a result of the sub-radio signal processor by an intermediate frequency combiner. The optical transceiver 242 may transmit the signal including the combined result to the digital signal processing matching device through the intermediate frequency.

According to one embodiment, the control signal may be a signal for a fault inquiry of the main radio signal processing apparatus or the sub-radio signal processing apparatus. In this case, the control unit 212 may check the failure state change of the main wireless signal processing device at a predetermined period, and the optical transmitting / receiving unit 242 may transmit the failure state change of the main wireless signal processing device.

According to one embodiment, the modems 222, 223, and 224 of FIG. 3 may share a failure state change with the sub wireless signal processing device through the failure presence / absence information signal. When a failure state change of the sub wireless signal processing apparatus is confirmed, the failure state change of the main wireless signal processing apparatus and the failure state change of the sub wireless signal processing apparatus can be transmitted to the digital signal processing matching apparatus according to the preset priority.

According to another embodiment, the control signal may be a signal for status inquiry or setting control of the main radio signal processing apparatus or sub-radio signal processing apparatus. Accordingly, the optical transceiver 242 can transmit the state or control result of the main wireless signal processing device or the sub wireless signal processing device to the digital signal processing matching device.

The types of management control frames included in the control signal will be described below with reference to Table 1. [

The RoF-based mobile front hall management control frame can be composed of a Head frame, an Information frame, a Body frame, and a Tail frame.

The Head frame may include an SOF field indicating the start of a frame. SOF can have a fixed value of 0x16161616.

The information frame includes a BODY_LEN field indicating the length of the body frame of the frame. For example, if the Body frame is 500 Bytes, it can be displayed as BODY_LEN = 0x01F4.

The BODY frame contains the main fields of the management control frame. The SUB_ID field indicates the module ID of the remote RU. For example, SUB_ID = 0x01FFFF may refer to RU1 131 of the first 3-sector RU of FIG. For reference, the SUB_ID field can define the destination of the management control frame together with the MCODE field. The CMD field may define an administrative control command via an administrative control frame. Each command can have a combination of query-response. If a bad frame has been received for the inquiry / request / response or the command can not be executed, the control unit 211 or the control unit 212 of FIG. 2 sets an error code value in the SUB_DATA field by an error response (CMD = 0x07) can do. The MCODE field can define the type of RoF-based mobile front-end equipment. 0x00 when the destination of the management control frame is the DIU 120, and 0x01 when the destination of the management control frame is the RU (130). However, the unit RU of the 3-sector RU can be defined in the SUB_ID field. The SUB_DATA_LEN field can define the length of the SUB_DATA field. The SUB_DATA field can be used by defining data according to each command. The Cyclic Redundancy Check (CRC) field can be used to identify data errors from SUB_ID to SUB_DATA upon frame reception.

The tail frame may include an EOF field indicating the end of a frame. For example, the EOF field may have a fixed value of 0x03.

110: Local management terminal
120: Digital signal processing matching device
130: Radio signal processing device
140: Digital signal processing device
150: Antenna

Claims (16)

A mobile front-hole management control method performed by a digital signal processing matching unit,
Receiving a management control frame from a local management terminal;
Controlling the digital signal processing matching unit based on the management control frame when the management control frame is for the digital signal processing matching unit; And
Transmitting a control result to the digital signal processing matching unit to the local management terminal;
The mobile front-hole management control method comprising:
The method according to claim 1,
And transmitting the control signal of the intermediate frequency including the management control frame to the radio signal processing unit when the management control frame is for a radio signal processing unit connected to the digital signal processing matching unit
Mobile Front Hole Management Control Method.
3. The method of claim 2,
Receiving a report signal including a control result for the radio signal processor from the radio signal processor; And
And transmitting a control result to the radio signal processing unit to the local management terminal
Mobile Front Hole Management Control Method.
3. The method of claim 2,
Wherein the transmitting comprises:
Mapping the frequency of the control signal to the intermediate frequency;
Combining the modulated control signal and the data signal;
Electro-optically converting the combined signal; And
And transmitting the electro-optically converted signal to the wireless signal processing unit
Mobile Front Hole Management Control Method.
The method of claim 3,
The method of claim 1,
Converting the report signal into a photo-electrical signal; And
Further comprising demodulating the pre-converted report signal
Mobile Front Hole Management Control Method.
The method according to claim 1,
If the management control frame is for a fault inquiry of the digital signal processing matching unit,
Wherein the step of controlling includes checking a change in the failure state of the digital signal processing matching unit at a predetermined period,
Wherein the transmitting step transmits the confirmation result to the digital signal processing matching unit to the local management terminal
Mobile Front Hole Management Control Method.
The method according to claim 1,
When the management control frame is for status inquiry of the digital signal processing matching unit,
Wherein the controlling step comprises the steps of: inquiring a state of the digital signal processing matching unit;
Wherein the transmitting step transmits the inquiry result to the digital signal processing matching unit to the local management terminal
Mobile Front Hole Management Control Method.
The method according to claim 1,
When the management control frame is for setting control of the digital signal processing matching unit,
Wherein the controlling step sets the digital signal processing matching unit,
The transmitting step may include transmitting the setting result of the digital signal processing matching unit to the local management terminal
Mobile Front Hole Management Control Method.
A mobile front-hole management control method performed by a main wireless signal processing unit,
Receiving a control signal for a downloading intermediate frequency including a management control frame from the digital signal processing matching unit;
Extracting the management control frame from the control signal;
Controlling the main radio signal processing unit based on the management control frame; And
And transmitting the control result to the digital signal processing matching unit
The mobile front-hole management control method comprising:
10. The method of claim 9,
Wherein the extracting comprises:
Pre-converting the control signal; And
And separating the data signal from the pre-pre-converted control signal,
Wherein the frequency of the separated control signal is mapped to the download intermediate frequency,
Mobile Front Hole Management Control Method.
10. The method of claim 9,
And transmitting the control signal to the sub wireless signal processing unit when the management control frame is for the sub wireless signal processing unit
Mobile Front Hole Management Control Method.
10. The method of claim 9,
Wherein the transmitting comprises:
Mapping a frequency of a report signal including the control result to an uploading intermediate frequency;
Combining the modulated reporting signal with a reporting signal of a sub-radio signal processing unit;
Electro-optically converting the combined signal; And
And transmitting the electro-optically converted signal to the digital signal processing matching unit
Mobile Front Hole Management Control Method.
10. The method of claim 9,
When the management control frame is for failure inquiry of the main signal processing unit,
Wherein the controlling step checks a change in the failure state of the main signal processing unit at regular intervals,
The transmitting step may include transmitting the confirmation result to the main signal processing unit to the local management terminal
Mobile Front Hole Management Control Method.
14. The method of claim 13,
Further comprising the step of sharing the fault state change with the sub radio signal processing unit through the fault presence / absence information signal,
The method of claim 1,
When a failure state change of the sub wireless signal processing unit is confirmed, a failure state change of the main wireless signal processing unit and a failure state change of the sub wireless signal processing unit are transmitted to the digital signal processing matching unit according to a preset priority
Mobile Front Hole Management Control Method.
10. The method of claim 9,
When the management control frame is for status inquiry of the main wireless signal processing unit,
Wherein the step of controlling comprises: inquiring a state of the main wireless signal processing unit,
Wherein the transmitting step transmits the inquiry result of the main wireless signal processing unit to the digital signal processing matching unit
Mobile Front Hole Management Control Method.
10. The method of claim 9,
When the management control frame is for setting control of the main radio signal,
Wherein the controlling step sets the main radio signal processor,
The transmitting step may include transmitting the setting result of the main wireless signal processing unit to the digital signal processing matching unit
Mobile Front Hole Management Control Method.

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