KR100747109B1 - Module management system for repeater - Google Patents

Abstract

The present invention relates to a module management system for efficiently managing a plurality of modules constituting a relay device. A module management system for a relay device according to the present invention includes a control module 100, the relay device comprising a plurality of modules 110, the module 110 is each unique to store unique identification information Identification information storage means 111, the unique identification information storage means 111 is configured to access the unique identification information externally, the control module 100 is the unique identification at the start of the relay device Control means 101 for reading the unique identification information from the information storage means, and communication interface means 102 for coupling the control module 100 to the communication network, wherein the control means 101 reads the unique identification information. Provides information to the management server through a communication network, coupled to the control module 100 via a communication network, the tube for collecting and managing the unique identification information provided from the control means 101 It characterized in that the means comprises a.

Relay, Unique Identification, Module Replacement

Description

Module management system for repeater

1 is a block diagram showing the overall configuration of an optical repeater of the repeater to which the present invention is applied.

2 is a block diagram showing a specific configuration of the donor 20 in FIG.

3 is a block diagram showing a specific configuration of the remote 30 in FIG.

4 is a block diagram showing a module management system for a relay device according to another embodiment of the present invention.

*** Brief description of the main parts of the drawing ***

100: control module, 101: control unit,

102: Ethernet interface, 110: module,

111: unique identification information storage unit.

The present invention relates to a relay device used in, for example, a mobile communication system, and more particularly, to a module management system for efficiently managing a plurality of modules constituting the relay device.

In the case of a mobile communication system, a plurality of relay devices are provided in consideration of a communication shade area. As such a relay device, various kinds of devices such as an RF relay device and an optical relay device are used. In general, since the relay device is installed in a rough environment such as an exterior of a building, the component parts are frequently burned out. Therefore, the relay device is usually configured by modularizing each of the components so as to maintain good maintenance. The module constituting the relay device includes a plurality of modules such as a power module, a control module, an RF module, and an optical module, and these modules are configured to be easily detachable from the relay device.

On the other hand, a company providing a communication service manages a large number of relay devices, and a lot of manpower and costs are required for maintenance of these relay devices. However, since it is difficult to aggregate appropriate data on the maintenance of these relays, there is a disadvantage in that efficient relay management is not achieved.

For example, in the case of intensive failure of a particular module in many relays, it is determined whether the abnormality of the module is caused by the environment or the error of the module itself, or according to the manufacturer producing the module. It is desirable to determine whether a failure occurs and take appropriate countermeasures. However, in reality, it is not easy to secure data on which module of the relay device mainly causes a failure.

Accordingly, an object of the present invention is to provide a module management system for a relay device that can be efficiently managed for a plurality of modules constituting the relay device, which has been created in view of the above circumstances.

A module management system for a relay device according to the first aspect of the present invention for realizing the above object is a relay device comprising a plurality of modules including a control module, each module stores the unique identification information A unique identification information storage means, wherein the unique identification information storage means is configured to externally access the unique identification information, and the control module receives the unique identification information from the unique identification information storage means at the start of the relay device. A control means for reading and a communication interface means for coupling the control module to the communication network, the control means providing the unique identification information read out to the management server through the communication network, and the control module through the communication network. Combined, management means for collecting and managing the unique identification information provided from the control means It is characterized in that comprises.

In addition, the management means is characterized by identifying the replacement status of the module by comparing the unique identification information previously transmitted from the unique identification information transmitted from the control module.

In addition, the control module further includes a unique identification information storage means for nonvolatile storage of the read unique identification information, the previous unique identification information stored in the unique identification information storage means and the newly read unique It is characterized by identifying the replacement status of the module based on whether the identification information is the same.

In addition, a module management system for a relay device according to a second aspect of the present invention for realizing the above object is provided with a donor and a remote, each donor and remote is configured with a plurality of modules including a control module In the relay apparatus, each module includes a unique identification information storage means for storing the unique identification information, the unique identification information storage means is configured to externally access the unique identification information, the control of the donor and remote Each module reads the unique identification information from the unique identification information storage means at the start of the device, and the remote side control module sends the read out unique identification information to the donor side control module, and the donor side control module transmits to the communication network. A communication interface means for coupling to the remote identification module and the unique identification information read from the donor side module. And the management means for providing the unique identification information provided to the management server through the communication network and collecting and managing the unique identification information provided from the control means and coupled with the control module through the communication network. do.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings.

First, the present invention will be described by taking an example in which the failure state information of the optical relay device, among the optical modules constituting the optical relay device, can be efficiently collected.

1 is a block diagram showing the overall configuration of an optical relay device. In FIG. 1, the optical relay device includes a donor 20 and a remote 30, and the donor 20 and the remote 30 are coupled through an optical cable 50.

The donor 20 is coupled to the base station 10 through a cable 40 and coupled to the upper relay management server through Ethernet. The donor 20 converts an RF signal received from the base station 10, that is, a downlink signal, into an optical signal and transmits the optical signal to the remote 30 through the optical cable 50, and the uplink optical signal received from the remote 30. Is converted into an RF signal and transmitted to the base station 10 through the cable 40.

In particular, the donor 20 collects the replacement information of the optical module provided in the donor 20 and the replacement information of the optical module provided in the remote 30 and provides it to the relay device management server through Ethernet.

The remote 30 converts the downlink signal received from the donor 20 through the optical cable 50 to an RF signal, and the converted RF signal is transmitted to the antenna 70 through the cable 60 to provide a wireless network. Is sent out.

In particular, the remote 30 provides replacement information of the optical module provided to the donor 20 through the optical cable 50.

2 is a block diagram showing a specific configuration of the donor 20.

Also in FIG. 2, the donor 20 includes a control module 21, an RF module 22, and an optical module 23.

The control module 21 includes a control unit 211, a modem 212, and an Ethernet interface 213. The control unit 211 controls the entire relay device, and collects replacement information of the optical modules 23 and 32 provided in the present donor 20 and the remote 30 to be described later, and relays them through Ethernet. Provided to the device management server (not shown). The modem 212 modulates, for example, FSK-modulated control data transmitted from the controller 211 to the remote 30, and demodulates the FSK modulated signal received from the remote 30 to the controller 211. The Ethernet interface 213 is for matching the control module 21 with Ethernet.

The RF module 22 includes an amplifier 221 for amplifying the downlink signal received from the base station 10 and an amplifier 222 for amplifying the uplink signal output from the optical module 23. do.

The optical module 23 includes an all-optical converter 231, a photoelectric converter 232, a wavelength division multiplexer 233 (WDM: Wavelength Division Multiplexer), and a ROM 234.

The all-optical converter 231 converts the downlink signal applied from the RF module 22 and the FSK modulation signal from the control module 21 into an optical signal. The photoelectric conversion unit 232 converts an optical signal received through the wavelength division multiplexer 233 into an electrical signal. The wavelength division multiplexer 233 couples the optical signal output from the all-optical converter 231 to the optical cable 50, and converts the optical signal from the remote 30 received through the optical cable 50 to the photoelectric conversion unit. To the input of (232).

Here, the all-optical converter 231 and the photoelectric converter 232 apply a signal corresponding to the intensity of the output light and the received light to the control module 21, and in this case, the photoelectric converter 232 receives the received light. The analog voltage signal corresponding to the intensity of the signal is applied to the control module 21.

In the ROM 234, a series of data values corresponding to analog voltage signals applied from the photoelectric converter 232 to the control module 21, that is, light intensity data values received by the photoelectric converter 232 are stored. In addition to being stored, in particular, the unique identification information of the optical module 23 is stored. These light intensity data values and the unique identification information are referred to by the control module 21. That is, when the donor 20 is activated, the control module 21 reads the light intensity data value and the unique identification information stored in the ROM 234 and stores them in the internal memory. The light intensity data value is used as data for determining an analog voltage value applied from the photoelectric conversion unit 232, and the unique identification information is data for determining whether the optical module 23 is replaced with another one. It will be used as.

3 is a block diagram showing a specific configuration of the remote 30 in FIG.

In Figure 3 the remote 30 is a control module 31. The optical module 32, the RF module 33 and the duplexer 34 is provided.

Here, the optical module 32 and the RF module 33 is substantially the same configuration as described in FIG.

That is, the optical module 32 couples the optical signal from the donor 20 received through the optical cable 50 to the photoelectric conversion unit 322 and transmits the optical signal applied from the all-optical conversion unit 323 to the optical cable 50. The wavelength division multiplexer 321 to be coupled to the light, and the photoelectric conversion unit 322, the RF module 33, and the control module 31 for converting an optical signal input from the wavelength division multiplexer 321 into an electrical signal. A ROM for storing a series of data values corresponding to the light intensity received by the photoelectric conversion unit 322 and the unique identification information of the optical module 32. 324 is configured.

In addition, the RF module 33 includes an amplifier 351 for amplifying the downlink signal applied from the optical module 32 and an amplifier 332 for amplifying the uplink signal applied from the duplexer 33. It is configured by.

On the other hand, the control module 31 is provided with a control unit 311 and the FSK modem 312 like the control module 21 of FIG. Here, the control unit 21 controls the entire remote 30, although not specifically shown in the drawings, especially when the remote 30 is activated, the light intensity data value and the uniqueness of the optical module 32 from the ROM 324. Read the identification information. Then, the unique identification information to be read is provided to the donor 20 through the modem 312. That is, the unique identification information of the optical module 321 provided from the controller 311 to the modem 312 is, for example, FSK-modulated by the modem 312, and the modulated signal is the all-optical conversion unit 323 of the optical module 32. Is converted into an optical signal. The converted optical signal is coupled to the optical cable 50 through the wavelength division multiplexer 321 and transmitted to the donor 20 side.

In the donor 20, an optical signal applied through the optical cable 50 is applied to the photoelectric conversion unit 232 by the wavelength division multiplexer 233 to be converted into an electrical signal, and the converted signal is converted into a control module ( 212 is applied to the modem 212. The modem 212 selectively inputs (filters) the FSK modulation signal applied from the remote 30 to perform demodulation processing and then applies it to the control unit 211.

In the above configuration, first, in the donor 20, when power is supplied to the donor 20, the control unit 211 reads the light intensity data value stored in the ROM 234 of the optical module 23. It will be stored in an internal memory (not shown). In addition, the control unit 211 reads out the unique identification information stored in the ROM 234 and transmits it to the management server (not shown) through the Ethernet interface 213.

In addition, in the remote 30, as in the donor 20, the control unit 311 reads the light intensity data and the unique identification information from the ROM 324 of the optical module 32 at the initial startup. The light intensity data is stored in an internal memory (not shown), and the unique identification information is transmitted to the control unit 211 of the donor 20 through the modem 312. Subsequently, the controller 211 transmits the received unique identification information to the management server through the Ethernet interface 213.

On the other hand, although not shown in the figure, the management server compares the unique identification information of the optical modules (23, 32) provided from the donor 20 with the previous it is determined whether the corresponding optical module is replaced with another . Based on the determination result, the database (not shown) is updated, and if necessary, the operator is notified that the optical module has been replaced.

The embodiment described above shows an example in which the present invention is applied to an optical relay device, particularly an optical module of the optical relay device. This takes into account that the existing optical module has a ROM for storing the light intensity data. However, the present invention is not limited to a specific relay device and a specific module, and can be applied to the general relay device and all modules constituting the relay device in the same manner.

Figure 4 shows a module management system for a relay device according to another embodiment of the present invention, which is a generalization of the present invention.

In FIG. 4, the relay device includes a control module 100 and includes a plurality of modules 110: 110-1, 110-2,..., 110-n. These modules 110 include power modules, RF modules, optical modules, and the like.

The control module 100 is basically provided with a control unit 101 for controlling the entire relay device and an Ethernet interface 102 for Ethernet communication of the control module 100. The control unit 101 is combined with the relay device management server (not shown) which saw the Ethernet interface 102.

The other modules 110 except for the control module 100 are provided with unique identification information storage units 111: 111-1, 111-2,..., 111-n, in which unique identification information is stored non-volatile. . The control module 100 and the other modules 110 are coupled via a mutual address bus, data bus, and control bus when the corresponding module is mounted on the relay device.

The controller 101 reads the unique identification information from the unique identification information storage 111 provided in each module 110 when power is supplied to the apparatus and started. The read unique identification information is provided to the management server via Ethernet and used as a basis for determining whether the corresponding module 110 is replaced with another one.

The determination of whether to replace the modules 110 may be performed by the controller 101. However, in order to determine whether the control unit 101 replaces the modules 110, a memory for nonvolatile storage of the unique identification information of each module 110 in the control module 100 will be required.

In the present invention, it is possible to easily determine whether to replace each module constituting the relay device. Therefore, the failure state can be easily grasped for each module or for each manufacturing company producing each module.

In addition, in the present invention, since it is possible to immediately grasp the replacement state of the module, it is possible to determine whether the maintenance is performed for the relay device in which the failure occurs.

Therefore, according to the present invention, the maintainability of each relay device constituting the relay network can be greatly improved, and a high quality communication service can be provided to a communication subscriber.

In addition, this invention is not limited to the above-mentioned embodiment, It can implement in various deformation | transformation within the range which does not deviate from the technical right summary of this invention.

As described above, according to the present invention, it is possible to implement a module management system for a relay device which enables efficient management of a plurality of modules constituting the relay device.

Claims (4)

In the relay device comprising a plurality of modules including a control module, The module has a unique identification information storage means for storing the unique identification information, respectively, The unique identification information storage means is configured to externally access the unique identification information, The control module includes control means for reading the unique identification information from the unique identification information storage means at the start of the relay device, and communication interface means for coupling the control module to the communication network, The control means provides the read unique identification information to the management server through the communication network, It is coupled to the control module via a communication network, and comprises a management means for collecting and managing the unique identification information provided from the control means, And said management means compares the unique identification information previously transmitted from said control module with the unique identification information transmitted later to determine replacement status of said module. delete The method of claim 1, The control module further includes a unique identification information storage means for nonvolatile storage of the read unique identification information, and the previous unique identification information and the newly read unique identification information stored in the unique identification information storage means. The module management system for a relay device, characterized in that to determine the replacement status of the module based on whether or not the same. In the relay device comprising a donor and a remote, each donor and remote comprises a plurality of modules including a control module, The module has a unique identification information storage means for storing the unique identification information, respectively, The unique identification information storage means is configured to externally access the unique identification information, The donor and remote control modules respectively read the unique identification information from the unique identification information storage means at the start of the device, The remote control module transmits the read unique identification information to the donor control module, The donor side control module has a communication interface means for coupling to a communication network to provide the unique identification information read from the donor side module and the unique identification information provided from the remote side control module to the management server through the communication network, And a management means coupled to the control module via a communication network, the management means collecting and managing unique identification information provided from the control means.

Images