KR100428676B1 - basestation transmission system - Google Patents

Abstract

The present invention provides a channel board for allocating a channel to call data signals inputted from mobile communication terminals and processing digitally assigned data, and whether the digital signal inputted from the channel board is a call data signal or a pilot signal. In this case, the call data signal is assigned to the first path and the pilot signal is assigned to the second path, respectively, and the digital signal distribution board controls the overall function of the base station transmitter, and the first and the first signals of the digital signal distribution board. A D / A conversion board for converting a plurality of digital signals respectively inputted from the second path into analog signals and then converting the digital signals into high frequency signals and transmitting call data signals among two paths of the D / A conversion board; A transmission amplifier that amplifies and outputs a high frequency signal output from one path, and a high frequency data signal output from the transmission amplifier. In addition to filtering and band filtering, amplifying high frequency pilot signals directly input from the second path of the D / A conversion board without passing through the transmission path of the transmission amplifier, and then band filtering them to the outside through an antenna. The present invention provides a base station transmitting apparatus comprising a transmitting filter module for emitting.

As described above, the present invention generates a hard handoff pilot signal identical to the output of the base station by integrating a hard handoff circuit in a separate block of the base station transmitter, thereby requiring a pilot unit in a separate space for hard handoff. As a result, the spatial design of the base station transmitter is improved.

Description

Base station transmission system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a base station transmitter, and more particularly, to a base station transmitter that generates a hard handoff pilot signal identical to a base station output by integrating a hard handoff circuit in a separate block of the base station transmitter.

In general, a base station system processes a call by assigning a call channel to a mobile communication terminal in its sector. Here, the mobile terminal frequently moves away from a base station to which a communication channel is allocated during a call and moves to a cell or another sector under the control of another base station. In this case, the neighboring base station is a new channel instead of a radio frequency channel in use. This function allows the call to be maintained by performing a handover or handoff function. However, the above-described base station uses the strength of the received signal and the carrier to interference ratio (C / I) and the like as parameters for determining the necessity of handoff of the mobile communication terminal.

For example, in the CDMA cellular system in which the handoff process is performed, the wireless channel being used and the newly allocated wireless channel are simultaneously occupied in order to prevent an instantaneous disconnection of the communication channel. When the signal of the newly allocated wireless channel becomes dominant, a method of completely switching over and recovering the previously used wireless channel is applied. This is called soft handoff. On the other hand, the conventional handoff method is called a hard handoff. The hard handoff method is a radio of an A cell without time occupying the radio channel of the A cell and the B cell to be transferred simultaneously. The channel is recovered and occupies the radio channel of the B cell.

In this case, in order to enable frequency hard handoff between two base stations having different frequency assignments, a single frequency base station radiates a pilot signal corresponding to a multi-frequency to a multi-frequency base station. The handset is available for frequency hard handoff to a single base station. Accordingly, the conventional single frequency base station as described above is usually provided with a hard handoff circuit for emitting a pilot signal.

Then, referring to FIG. 1, the base station transmitter 70 separately provided with the conventional hard handoff circuit may be divided into a signal transmitter 71 and a hard handoff circuit unit 72. The transmitting unit 71 allocates a channel to mobile communication terminals (not shown) and inputs the channel unit 73 for digital signal processing of data transmitted from the mobile communication terminal to which the channel is assigned, and the channel unit 73. A digital signal distribution board 74 for outputting the digital data signal to a specific transmission path and controlling the functions of the base station transmitter 70, and a digital signal input from the digital signal distribution board 74. A D / A conversion board 75 for converting and converting an analog signal into a high frequency signal, and a transmission amplifier 76 for amplifying and outputting a high frequency signal output from the D / A conversion board 75; Send the Transmitting filter module 78 for band-pass filtering the high-frequency signal output from the amplifier 76 to the outside through the antenna 77.

In addition, the hard handoff circuit unit 72 is a pilot signal generator 79 for generating a pilot signal for hard handoff of the mobile communication terminal entering the base station sector, and the pilot signal output from the pilot signal generator 79 A band pass filter 82 for band-pass filtering the pilot signal of the high frequency output from the transmit amplifier 80 and amplifying the signal to a predetermined level, and emitting it to the outside through the beacon antenna 81. It includes.

In addition, the D / A conversion board 75 includes a D / A converter 83 for converting a digital signal input from the digital signal distribution board 74 into an analog signal, as shown in FIG. A baseband modulator 84 for modulating the analog data signal output from the A converter 83 into the baseband, and a frequency mixer for converting the baseband data signal input from the baseband modulator 84 into a high frequency signal; A band pass filter 86 for band-filtering the high frequency data signal output from the frequency mixer 85 to a predetermined band, and a high frequency data signal output from the band pass filter 86 at a predetermined level. And an amplifier 87 for amplifying the signal and a variable attenuator 88 for variably attenuating the high frequency data signal output from the amplifier 87.

In addition, the digital signal distribution board 74 arranges and outputs a data control unit 89 for controlling a plurality of digital signals input from the channel unit 73 and digital signals output from the data control unit 89. It includes an alignment unit 90 to.

Next, referring to the operation of the base station transmitter provided with the conventional hard handoff circuit as described above, first, the channel unit 73 of the signal transmitter 71 establishes a channel to the sector of the base station or the mobile communication terminals handed off. The digital signal is processed and input to the data control unit 89 of the digital signal distribution board 74 by allocating the data transmitted from each mobile communication terminal to which the channel is allocated. Then, the data control unit 89 of the digital signal distribution board 74 controls the input and output of the digital signal of the plurality of mobile communication terminals to be input to the alignment unit 90 of the digital signal distribution board 74. . In addition, the alignment unit 90 of the digital signal distribution board 74 sorts the digital signals input from the data control unit 89 to the D / A conversion unit 83 of the D / A conversion board 75. Enter it. At this time, the D / A converter 83 converts the input digital signal into an analog signal and inputs it to the baseband modulator 84. The baseband modulator 84 converts the analog data signal input from the D / A converter 83 into a baseband signal and inputs the same to the frequency mixer 85. Then, the frequency mixer 85 filters the input analog baseband signal, for example, harmonics and spurious components, converts the harmonic and spurious components into high frequency signals, and inputs them to the bandpass filter 86. In the band pass filter 86, the high frequency data signal input from the frequency mixer 85 is band-filtered and amplified by the amplifier 87 and input to the variable attenuator 88. The variable attenuator 88 variably attenuates the input high frequency data signal by a predetermined amount of attenuation and inputs the same to the transmission amplifier 76. In this case, the transmission amplifier 76 amplifies the high frequency data signal input from the variable attenuator 88 of the D / A conversion board 75 and transmits it to the transmission filter module 78. Then, the transmission filter module 78 band-passes the high frequency signal output from the transmission amplifier 76 to the outside through the antenna 77.

Here, the hard handoff circuit unit 71 of the base station transmits a pilot signal to the outside for the hard handoff between the base station and the base station separately from the data transmission operation of the base station. In this case, the hard handoff circuit unit 71 The pilot signal generator 79 generates a pilot signal for hard handoff of the mobile communication terminal entering the base station sector and inputs the pilot signal to the transmission amplifier 80. The transmission amplifier 80 amplifies the pilot signal output from the pilot signal generator 79 to a predetermined level and then inputs it to the band pass filter 82. Then, the band pass filter 86 of the hard handoff circuit unit 72 band-pass filters the high frequency pilot signal output from the transmission amplifier 80 and emits it to the outside through the beacon antenna 81. Therefore, if there is a mobile communication terminal moving into the cell of the base station, the hard signal is received by receiving a pilot signal transmitted through the antenna for the beacon 81.

However, the base station transmitter having a separate hard handoff circuit as described above has to be equipped with a hard handoff circuit part in a predetermined space separately from the transmitter of the base station. Therefore, the space design of the base station transmitter is considerably deteriorated, and the hard handoff circuit part must be installed separately regardless of the individual board of the base station transmitter. There was also a problem that deteriorates considerably.

Accordingly, the present invention has been invented to solve the above conventional problems, by integrating the hard handoff circuit in the individual block of the base station transmitting apparatus to generate the same hard handoff pilot signal as the base station output, hard handoff It is not necessary to provide a pilot unit in a separate space in order to provide a base station transmitter that improves the spatial design of the base station transmitter accordingly.

Another object of the present invention is to provide a base station transmitter, in which a hard handoff circuit is implemented using individual blocks of the base station transmitter, whereby the manufacturing cost of the base station transmitter is also significantly reduced.

According to an aspect of the present invention, there is provided a channel board for allocating a channel to call data signals input from mobile communication terminals and digitally processing the data allocated to the channel, and a digital signal input from the channel board. A digital signal distribution board which determines whether the call data signal is a pilot signal or a pilot signal and allocates the call data signal to the first path and outputs the pilot signal to the second path, respectively, and controls overall functions of the base station transmitter; A D / A conversion board for converting a plurality of digital signals respectively inputted from the first and second paths of the digital signal distribution board into analog signals and then converting and outputting them into a high frequency signal; and two paths of the D / A conversion board. A transmission amplifier for amplifying and outputting a transmission power of a high frequency signal output from a first path through which a call data signal is transmitted, and from the transmission amplifier In addition to channel filtering and band filtering the output high frequency data signal, the high frequency pilot signal directly input from the second path of the D / A conversion board is amplified and then band filtered without passing through the transmission path of the transmission amplifier. It provides a base station transmitter, characterized in that consisting of a transmission filter module for emitting a signal to the outside through an antenna.

1 is an explanatory diagram illustrating a conventional base station transmitter.

2 is an explanatory diagram illustrating a D / A conversion board of a conventional base station transmitter.

3 is an explanatory diagram for explaining a base station transmitter according to the present invention;

4 is an explanatory diagram illustrating a digital signal distribution board of the present invention.

<Detailed Description of Codes>

1: Channel board 2: Digital signal distribution board

3: D / A conversion board 4: Transmission amplifier

5: antenna 6: transmit filter module

7: Data control unit 8: Data distribution unit

9: Sorter 10: D / A converter

11: baseband modulator 12: frequency mixer

13: bandpass filter 14: amplifier

15: Variable Attenuator 16: Channel Filter

17: amplifier 18: band filter

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

The present invention provides a channel board (1) for allocating a channel to call data signals input from mobile communication terminals (not shown) and digitally processing the data to which the channel is allocated, as shown in FIG. It is determined whether the digital signal input from the board 1 is a call data signal or a pilot signal, and the call data signal is assigned to the first path and the pilot signal is assigned to the second path. A digital signal distribution board (2) for controlling and a plurality of digital signals respectively inputted from the first and second paths of the digital signal distribution board (2) are converted into analog signals and then converted into a high frequency signal and output. A transmission amplifier 4 that amplifies and outputs a high frequency signal output from a first path through which a call data signal is transmitted among two paths of the A conversion board 3 and the D / A conversion board 3; The song In addition to channel filtering and band filtering the high frequency data signal output from the amplifier (4), directly input from the second path of the D / A conversion board (3) without passing through the transmission path of the transmission amplifier (4). And a transmission filter module 6 for amplifying the high frequency pilot signals and then band filtering the signals to the outside through the antenna 5.

As shown in FIG. 4, the digital signal distribution board 2 includes a data control unit 7 for controlling a plurality of digital signals input from the channel board 1 and from the data control unit 7. A data divider 8 for distributing a data signal and a pilot-allocated signal among the input digital signals to a first path and a second path, respectively, and the data divider 8 along the first and second paths. And an alignment unit 9 for dividing the signals inputted from each other, and individually arranging the signals.

In addition, the D / A conversion board (3) is a D / A conversion unit 10 for converting each of the digital signals respectively inputted through the two paths of the digital signal distribution board (2) and outputs the two paths; And a baseband modulator 11 for modulating the analog data signals respectively inputted through the two paths of the D / A converter 10 to the baseband and outputting the signal to the two paths, respectively, of the baseband modulator 11. A frequency mixer 12 for converting baseband data signals respectively inputted through two paths into high-frequency signals and outputting them in two paths, respectively; and high-frequency data signals respectively inputted along two paths from the frequency mixer 12; The band pass filter 13 outputs the signals through two paths by band filtering the bands to the set bands, and amplifies the high frequency data signals input along the two paths of the band pass filter 13 to a predetermined level. Output The amplifier 14 and the variable attenuator 15 respectively attenuate the high frequency data signals input along the two paths of the amplifier 14 and output the two paths respectively.

In addition, the transmission filter module 6 performs a channel filter 16 for channel filtering the high frequency signal output from the transmission amplifier 4 and the D / A conversion without passing through the transmission path of the transmission amplifier 4. An amplifier 17 for amplifying a high frequency signal directly input from the board 3, and a high frequency data signal and a high frequency pilot signal input from the channel filter 16 and the amplification unit 17, respectively, to filter these signals. And a band filter 18 which emits to the outside through the antenna 5, respectively.

Next, the operation and effects of the apparatus of the present invention as described above will be described.

In case of call signal processing of each digital data received from mobile communication terminals in the device of the present invention, the channel board 1 of the device of the present invention first allocates a channel to the mobile communication terminals (not shown) and assigns the channel. The digital data signals transmitted from the mobile communication terminal are input to the data control unit 7 of the digital signal distribution board 2. Then, the data control unit 7 of the digital signal distribution board 2 controls the input / output of the digital signals of the plurality of mobile communication terminals which are input, and then inputs the data distribution unit 8 of the digital signal distribution board 2. Let's do it. Then, the data distribution unit 8 distributes a pilot-allocated signal and a data signal among the digital signals input from the data control unit 7 to a plurality of paths, that is, the first and second paths, respectively. When the signal input from the data control unit 7 is a call data signal, for example, the signal is output to the first path of the alignment unit 9. The sorting unit 9 classifies and sorts the call data signal input along the first path and then inputs the first data of the D / A converting unit 10 of the D / A converting board 3. In this case, the D / A converter 10 converts the digital signal input along the first path into an analog signal and inputs it into the first path of the baseband modulator 11. The baseband modulator 11 converts an analog data signal input from the first path of the D / A converter 10 into a baseband signal and inputs the same to the frequency mixer 12. Then, in the frequency mixer 12, the analog baseband signal input along the first path of the baseband modulator 11 is filtered, for example, the harmonic and the spurious component, and then converted into a high frequency signal to convert the bandpass filter 13 into a high frequency signal. Enter In the band pass filter 13, the high frequency data signal input along the first path of the frequency mixer 12 is band-filtered and amplified through the amplifier 14 and input to the variable attenuator 15. The variable attenuator 15 variably attenuates the high frequency data signal input along the first path of the amplifier 14 by a predetermined amount of attenuation and inputs it to the transmission amplifier 4.

In this case, the transmission amplifier 4 amplifies the transmission power of the high frequency data signal input along the first path of the variable attenuator 15 of the D / A conversion board 3 to transmit the channel filter of the transmission filter module 6. 16). The channel filter 16 performs channel filtering on the high frequency data signal input from the transmission amplifier 4 located on the first path line and inputs the same to the band pass filter 18 of the transmission filter module 6. Then, the band filter 18 of the transmission filter module 6 performs the normal call function by band-filtering the high frequency signal output from the channel filter 16 to the outside through the antenna (5).

In this process, if a signal to which a pilot for hard handoff is allocated is input to the channel board 1, the channel board 1 allocates a pilot signal for the hard handoff to a specific channel to perform a digital signal. Input to the data control unit 7 of the distribution board (2). Then, the data control unit 7 of the digital signal distribution board 2 controls the input / output of the input pilot signal and then inputs it to the data distribution unit 8 of the digital signal distribution board 2. Then, the data distributor 8 selects a second path among the plurality of paths and outputs the pilot signal input from the data controller 7 to the second path of the alignment unit 9. In addition, the alignment unit 9 classifies and aligns the pilot signal input along the second path, and then inputs it to the second path of the D / A conversion unit 10 of the D / A conversion board 3. At this time, the D / A converter 10 converts the pilot signal input along the second path into an analog signal and inputs it into the second path of the baseband modulator 11. The baseband modulator 11 converts an analog pilot signal input from the second path of the D / A converter 10 into a baseband signal and inputs it to the frequency mixer 12. Then, the frequency mixer 12 filters the analog pilot signal input along the second path of the baseband modulator 11, for example, the harmonics and the spurious components, and converts the harmonic and spurious components into high frequency signals to the band pass filter 13. Enter it. In the band pass filter 13, the high frequency data signal input along the second path of the frequency mixer 12 is band-filtered and amplified through the amplifier 14 and input to the variable attenuator 15.

In this case, the variable attenuator 15 variably attenuates the high frequency data signal input along the second path of the amplifier 14 by a set amount of attenuation so that the amplifying unit of the transmission filter module 6 does not go directly through the transmission amplifier 4. 17).

The amplifying unit 17 amplifies power enough to transmit a high frequency pilot signal directly input from the variable attenuator 15 to the outside without passing through the transmission amplifier 4 along the second path, thereby transmitting a transmission filter module ( Input to the bandpass filter 18 of FIG. 6). Then, the band pass filter 18 of the transmission filter module 6 performs a normal hard handoff function because the band filter 18 filters the pilot signal output from the amplifier 17 and radiates it to the outside through the antenna 5.

Here, the first path for transmitting the data signal is composed of a digital signal distribution board (2), a D / A conversion board (3), a transmission amplifier (4), a channel filter (16) and a band filter (18), The second path for pilot signal transmission includes a digital signal distribution board 2, a D / A conversion board 3, an amplifier 17, and a band filter 18.

Meanwhile, according to another embodiment of the present invention, the modulation characteristics of the current transmission output waveform may be measured between the transmission filter module 6 and the antenna 5 during normal operation of the base station. By using the result, the signal related to the base station transmit power is corrected, thereby improving the quality of the transmit output signal.

That is, according to the present invention, a pilot can be generated from a base station resource by allocating a channel for pilot signal to the channel board 1 of the corresponding base station, and can perform a conventional pilot beacon function with a signal almost identical to the base station signal. have. In addition, by implementing a conventional pilot beacon function in a separate board of the base station transmitter, it is possible to directly and accurately control and control the state of the hard handoff function of the base station. In addition, since the transmission output signal of the base station can be measured during operation of the base station, it is possible to optimize the operating state of the base station.

As described above, the present invention integrates the hard handoff circuit in the individual block of the base station transmitter to generate the same pilot signal for hard handoff as the output of the base station, thereby requiring a separate pilot unit for hard handoff. Therefore, there is an advantage to improve the space design of the base station transmitter accordingly.

In addition, according to the present invention, it is possible to measure the modulation characteristics of the transmission output waveform of the base station itself, thereby improving the quality of a signal related to the transmission output of the base station.

Claims (6)

A channel board for allocating channels to call data signals input from mobile communication terminals and digitally processing the data allocated to the channels; It is determined whether the digital signal input from the channel board is a call data signal or a pilot signal, and the call data signal is assigned to the first path and the pilot signal is assigned to the second path, respectively, and the overall function of the base station transmitter is controlled. Digital signal distribution board, A D / A conversion board for converting a plurality of digital signals respectively inputted from the first and second paths of the digital signal distribution board into analog signals and then converting and outputting them into high frequency signals; A transmission amplifier for amplifying and outputting a transmission power of a high frequency signal output from a first path through which call data signals are transmitted among two paths of the D / A conversion board; After channel filtering and band filtering the high frequency data signal output from the transmission amplifier, amplifying the high frequency pilot signal directly input from the second path of the D / A conversion board without passing through the transmission path of the transmission amplifier. And a transmission filter module for band-pass filtering and transmitting these signals to the outside through an antenna. The digital signal distribution board of claim 1, wherein the digital signal distribution board comprises a data controller for controlling a plurality of digital signals input from a channel board, and a data signal and a pilot assigned signal among digital signals input from the data controller. And a data divider for distributing the first and second paths, and an alignment unit for dividing, individually arranging, and outputting signals input from the data divider along the first and second paths. Base station transmitter. According to claim 1, wherein the D / A conversion board is a D / A conversion unit for converting each of the digital signal input through the two paths of the digital signal distribution board to the analog signal respectively and outputs the two paths, A baseband modulator for modulating the analog data signals respectively inputted through the two paths of the D / A converter to the baseband and outputting them to each of the two paths; A frequency mixer for converting baseband data signals respectively inputted through two paths of the baseband modulator into high frequency signals and outputting them in two paths; A band pass filter for band-filtering the high-frequency data signals inputted along the two paths of the frequency mixer into the set bands and outputting them in the two paths, respectively; An amplifier for amplifying a high frequency data signal respectively inputted along two paths of the bandpass filter to a predetermined level and outputting the two signals respectively; And a variable attenuator configured to variably attenuate data signals of high frequencies respectively inputted along two paths to the amplifier and output the two attenuated data signals. The transmission filter module of claim 1, wherein the transmission filter module amplifies a channel filter for channel filtering the high frequency signal output from the transmission amplifier, and a high frequency signal input directly from the D / A conversion board without passing through the transmission path of the transmission amplifier. And a band pass filter for band-passing the high frequency data signals and the high frequency pilot signals respectively inputted from the channel filter and the amplification unit and emitting these signals to the outside through an antenna. The digital signal distribution board according to claim 1 or 4, wherein the first path passes through a digital signal distribution board, a D / A conversion board, a transmission amplifier, a channel filter, and a band pass filter. A base station transmitter characterized in that via the / A conversion board, the amplifier and the band pass filter. delete