KR20060014113A - Repeater for mobile communications system capable of selecting a channel frequency - Google Patents

Abstract

The present invention relates to a relay device used in a personal mobile communication system or a cellular system. According to the present invention, there is provided a relay device for a mobile communication system having a channel frequency selection function, which allows the channel frequency corresponding to a communication channel with a base station or another relay device to be arbitrarily changed and set. The relay apparatus of the present invention includes first and second antennas for transmitting and receiving a frequency signal of a predetermined band, first amplifying means for amplifying a frequency signal received through the first antenna, and the second antenna. A second amplifying means for amplifying the received frequency signal, a digital filter provided in front of the first amplifying means or the second amplifying means, and a control means for controlling the digital filter based on input data from an external device. And the digital filter filters a frequency signal of a specific band from a frequency signal received through an antenna under the control of the control means, and converts the frequency band of the filtered frequency signal into a frequency signal of another band. It is characterized by.

Repeater, Repeater, Channel Selection, Variable Repeater

Description

Repeater for mobile communications system capable of selecting a channel frequency}

1 is a block diagram illustrating a network configuration for providing a communication function to a subscriber station using a base station and a repeater in a mobile communication system.

Figure 2 is a block diagram showing the configuration of a relay device for a mobile communication system having a channel frequency selection function according to an embodiment of the present invention.

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

201, 211: antenna, 202, 210: duplex filter,

206, 215: digital filter, 220: processor,

221: access point, 222: channel memory.

The present invention relates to a relay device for use in a personal mobile communication system or a cellular system, and more particularly, a mobile device having a channel frequency selection function that allows a user to arbitrarily vary a channel frequency corresponding to a communication channel with a base station or another relay device. A relay device for a communication system.                         

Recently, a mobile communication system that enables a user to perform voice calls and data transmission and reception while traveling is widely used. Such a mobile communication system divides a call area into cell units, and sets base stations for each cell unit so that users can perform communication through these base stations. These base stations and terminals usually perform data transmission and reception using frequency signals between several hundreds of MHz and several kilohertz, and also install and operate a plurality of relay devices in consideration of communication shadow areas such as indoors.

1 is a block diagram illustrating a network configuration for providing a communication function to a subscriber station using a base station and a repeater in a general mobile communication system. In the drawing, reference numeral 100 denotes a base station that provides a communication service for a subscriber station (not shown) within a certain cell coverage, and 200 (200-1 to 200-n) are installed in a communication shade area within the base station. Relay device for facilitating data transmission and reception between the base station 100 and 300 is the relay device 200 when the line of sight between the relay device 200 and the base station 100 is not secured. It is a relay device for smoothly transmitting and receiving signals between the base station (100). The relay device 300 is also referred to as a master and the relay device 200 is also referred to as a slave relay device.

In the above configuration, the base station 100 and the relay device 200 transmit and receive data through a predetermined fixed channel frequency, and in particular, in the case of the master relay device 300, a relay device different from the transmission / reception frequency with the base station 100. That is, when the transmission and reception frequencies of the slave relay apparatus 200 are set to be the same, the frequency signal transmitted through the transmitter is input and amplified again through the receiver, causing the relay apparatus to oscillate, thereby causing the relay to oscillate. The transmission / reception frequency between the apparatus 300 and the transmission / reception frequency between the relay apparatuses 300 and 200 are set differently.

However, in the above-described system, since the frequencies capable of transmitting and receiving the relay apparatuses 200 and 300 are fixedly set, there is a problem that the degree of freedom in system configuration and operation is very low.

That is, generally, the number of communication channels that can be operated by the base station 100, that is, the number of channel frequencies typically reaches several dozen, and in the case of the operator who operates the base station 100, the communication is performed through the base station 100 or the relay device 200. The communication channel is allocated and operated in consideration of the number of subscribers who are provided with the service. Therefore, when the number of subscribers receiving communication service through the base station 100 increases or decreases, or a change in the service environment of the region occurs, it is necessary to change the frequency channel serviced through the base station 100.

However, in the case of the conventional relay apparatuses 200 and 300 as described above, since the transmission / reception frequency is fixed, if the frequency channel serviced by the base station 100 is changed, the relay apparatuses 200 and 300 are changed. There is a problem that needs to be replaced. In addition, this lowers the degree of freedom in operating the base station of the service provider, which ultimately acts as a barrier to providing the best communication quality for the subscriber who receives the communication service using the base station 100.

Accordingly, the present invention was created to solve the above-described problems, and the relay for the mobile communication system having a channel frequency selection function that allows the operator to easily change and set the channel frequency that can be transmitted and received by the relay device as needed. The object is to provide a device.

In accordance with an aspect of the present invention, a repeater for a mobile communication system having a channel frequency selection function includes first and second antennas for transmitting and receiving a frequency signal of a predetermined band and received through the first antenna. A first amplifying means for amplifying a frequency signal, a second amplifying means for amplifying a frequency signal received through the second antenna, a digital filter installed in front of the first amplifying means or the second amplifying means, and an external device Control means for controlling the digital filter based on input data from a device, wherein the digital filter filters a frequency signal of a specific band from a frequency signal received through an antenna under the control of the control means, The frequency band of the filtered frequency signal may be converted into a frequency signal of another band.

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

Figure 2 is a block diagram showing the configuration of a relay device for a mobile communication system having a channel frequency selection function according to the present invention. This relay device corresponds to the master or slave relay device in FIG. 1.

In FIG. 2, the relay device includes first and second transmit / receive antennas 201 and 211. Here, the first antenna 201 is for transmitting and receiving data with the base station 100 or another relay device, and the second antenna 211 is for transmitting and receiving data with another relay device or service terminal. Hereinafter, for convenience, the first antenna 201 transmits and receives a frequency signal with the base station 100, and the second antenna 211 transmits and receives a frequency signal with another relay device.

The frequency signal received from the base station 100 received through the first antenna 201 is applied to the first low noise amplifier (LNA) 203 through the first duplex filter 202 and the first low noise. The frequency signal amplified by the amplifier 203 is converted into low frequency through a first frequency down converter (DC), and then converted into digital data through a first analog / digital converter 205 to be a first digital filter 206. ) Is entered.

The digital data output from the first digital filter 206 is converted into an analog signal through the first digital / analog converter 207, and the analog signal is converted into a first frequency up converter (UC) 208. Is converted into a high frequency signal. Subsequently, the high frequency signal output from the first frequency up-converter 208 is amplified as a high output frequency signal through a first high power amplifier (HPA) 209, and then the second duplex filter 210 It is transmitted through the second antenna 211.

The frequency signal from the other relay device received through the second antenna 211, that is, the slave relay device 200 in FIG. 1, is the same as the frequency signal received through the first antenna 201 described above. It is transmitted to the base station 100 through the first antenna 201.

That is, the frequency signal received through the second antenna 211 is applied to the second low noise amplifier 212 through the second duplex filter 210 and amplified, and is output from the second low noise amplifier 212. The second signal is converted into a low frequency signal through the second frequency down converter 213, and then converted into digital data through the second analog / digital converter 214 and input to the second digital filter 215.

Subsequently, the digital data output from the second digital filter 215 is converted into an analog signal through the second digital to analog converter 216 and then converted into a high frequency signal by the second frequency up-converter 217. The high frequency signal output from the second frequency up-converter 217 is amplified by the second high power amplifier 218 and then transmitted to the base station 100 through the first duplex filter 202 and the first antenna 201. do.

The first and second digital filters 206 and 215 are substantially the same. These digital filters 206 and 215 have a function of selectively filtering the frequency signals of the entire channel frequency band that can be provided between the base station 100 and the service terminal and converting them into any other frequency signal. Channel selection and frequency conversion operations in these first and second digital filters 206 and 215 are performed by control data applied from the processor 220.

The processor 220 controls the first and second digital filters 206 and 215 based on the control information stored in the channel memory 222. The channel memory 222 stores channel information used for data transmission from the base station 100 to the service terminal and channel information used for data transmission from the service terminal to the base station. Frequency information of the channel information is stored corresponding to the channel information. These information are queried by the processor 220 as described above.

In addition, the processor 220 is coupled to an operator terminal (not shown), for example, via an access point 2221. This access point 221 is for wireless LAN connection between the present relay device and the operator terminal device. Of course, the connection between the relay device and the operator terminal device can use other well-known interface means.

The operator can access the relay device using the operator terminal device. The operator may set a communication channel and a frequency of the communication channel used between the base station 100 and the service terminal or the base station 100 and the relay device 200 using the operator terminal device. The channel information input and set by the operator is stored in the channel memory 222 by the processor 220. The processor 220 controls the first and second digital filters 206 and 215 based on the information stored in the channel memory 222 to transmit / receive a frequency channel between the base station 100, the relay device, or the service terminal. Will be set and assigned.

In the above embodiment, after the operator accesses the relay apparatus using the operator terminal apparatus, the operator repeats the relay apparatus with a simple operation of updating the channel information and the frequency information stored in the channel memory 222 using the operator terminal apparatus. It is possible to set the transmission / reception channel and its channel frequency. Therefore, the case where the transmission / reception channel between the base station 100 and the service terminal is changed due to a change in the service environment can be easily responded without any additional hardware change or addition.

In addition, the above-described embodiment may be applied to both the master relay 300 and the slave relay 200 in the same manner in FIG. 1, and also in the embodiment of FIG. 2, the first and second digital filters ( Only one of the 206 and 215 may be installed as necessary.

That is, the present invention is not limited to the above-described embodiments and can be implemented in various ways within the scope not departing from the technical gist of the present invention.

As described above, according to the present invention, it is possible to realize a repeater for a mobile communication system having a channel frequency selection function that enables an operator to easily change and set a channel frequency that can be transmitted and received by the repeater as needed.

Claims (2)

First and second antennas for transmitting and receiving frequency signals of a predetermined band; First amplifying means for amplifying a frequency signal received through the first antenna, Second amplifying means for amplifying a frequency signal received through the second antenna; A digital filter installed at the front end of the first amplifying means or the second amplifying means; And control means for controlling the digital filter based on input data from an external device, The digital filter filters a frequency signal of a specific band from a frequency signal received through an antenna under the control of the control means, and converts the frequency band of the filtered frequency signal into a frequency signal of another band. Repeater for mobile communication system with frequency selection function. The method of claim 1, And the control means is coupled to an external device through an access point.

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