KR200340083Y1 - LPA changing device of the mobile communication base-station - Google Patents

Abstract

The present invention as described above has a splitter for separating the output signal of the LPA between the output terminal of the plurality of LPA and the multi-directional antenna provided on the RF board of the base station and switching means for connecting the output of the splitter to cross each other, LPA failure By switching to normal LPA through switching devices, it is not necessary to have a separate complicated redundancy circuit for switching the failed LPA. Therefore, the manufacturing cost of the mobile communication base station can be considerably reduced, as well as the LPA switching provided in the RF board. The circuit configuration for the system can be easily designed with only splitters and switching, thereby significantly improving the spatial design of the mobile communication base station.

Description

LPA changing device of the mobile communication base-station

The present invention relates to a linear power amplifier switching device of a mobile communication base station, and in particular, a splitter for separating the output signal of the LPA between the output terminal of the multiple LPA and the multi-directional antenna provided on the RF board of the base station and the output of the splitter The present invention relates to a linear power amplifier switching device of a mobile communication base station having an alternately connected switching means and switching to a normal LPA through a switching means in case of an LPA failure.

In general, mobile communication systems have been rapidly developed as the industrial society has spread rapidly. In the early 1980s, the mobile communication system was divided into hexagonal cells of several km to several ten kilometers in diameter, and then in geographically separated cells. The mobile communication system has grown rapidly by using a cellular mobile communication system that uses the same frequency channel repeatedly and implements a radio channel switching function between cells as the subscriber moves.

On the other hand, these mobile communication systems typically use FDMA, TDMA and CDMA as their access methods, among which CDMA modulates a transmission signal by assigning different codes with low correlation to each subscriber and transmits the code to the receiver. Demodulation is performed with the same code. The terminal or base station transmission system using the CDMA method has a very good advantage over other methods in terms of line capacity, security, and economical efficiency. The CDMA signal of the base station transmission system usually uses a CDMA signal. And an up / down converter circuit for converting the signal into a high frequency signal and outputting it to the outside. At this time, the up / down converter circuit of the base station RF board can detect multiple power input level signals radiated to three sectors (SECTOR) in multi directions (alpha, beta, gamma) for power control. It consists of a multipath structure.

Then, referring to the conventional base station RF board as described above with reference to FIG. 1, the CDMA transmission signal inputted from the digital card (not shown) of the base station is outputted in frequency up to a predetermined level RF signal or vice versa. A plurality of LPAs 71A- which are connected to a plurality of up / down converters 70A-B and output terminals of the plurality of up / down converters 70A-B, respectively, and amplify the output RF signal to a high output. C; a linear power amplifier and RF signals outputted from the LPAs 71A-C, respectively, connected to the output terminals of the plurality of LPAs 71A-C, respectively, to filter the RF signals through the antennas 72A-C. The plurality of filters 73A-C emitting to alpha, beta, gamma, and an output terminal of the up / down converter 70A-C and an input terminal of the LPA 71A-C, respectively, A first switch 74 for switching the output signal of 70A-C and the output of the LPA 71A-C A second switch 75 connected between the stage and the filters 73A-C, respectively, to switch the output signal of the LPA 71A-C, and between the first switch 74 and the second switch 75; An LPA redundancy unit 76 which is switched when the one of the plurality of LPAs 71A-C fails and performs high power amplification on the output signal of the up / down converters 70A-C, and the first switch 74 A control unit 78 controls the switching function of the second switch 75 and the amplifier function of the LPA redundancy unit 76 and the overall function of the RF board 77.

Here, the up / down converters 70A-C of the base station as described above have at least three sectors (SECTOR) or more per multi-direction (alpha, beta, gamma) per base station.

On the other hand, referring to the operation of the conventional base station RF board, first, the base station emits the RF signal for each sector of the multi-directional sector, for example, at least three sectors (SECTOR) per alpha, beta, and gamma per base station. . At this time, the plurality of up / down converters 70A-C of the RF board 77 of the base station receive a low-frequency call signal from the lower digital card, and frequency-up it to the FR signal to control the controller 78. Outputs to the LPA 71A-C switched by the first switch 74 receiving the respective.

Then, each of the LPAs 71A-C amplifies the input RF signal to a high output and is output to the filters 73A-C by the second switch 75 which is controlled by the controller 78. Accordingly, each of the filters 73A-C filters the input RF signal and emits the RF signals in the directions set through the antennas 72A-C, that is, in the alpha, beta, and gamma directions.

In this case, the controller 78 checks the states of the plurality of LPAs 71A-C, and if any one of them fails, the controller 78 controls the switching contacts of the first switch 74 and the second switch 75 to perform the up operation. The output terminal of the / down converter 70A-C is switched to the LPA redundancy unit 76. Then, the output signal of the up / down converters 70A-C is input to the LPA redundancy unit 76 via the first switch 74. The LPA redundancy unit 76 is then inputted to the up / down converter 76A. The output signals of the down converters 70A-C are amplified to high output and input to the filters 73A-C via the second switch 75, respectively. Then, the filters 73A-C filter the input RF signal and emit the RF signals in the directions set through the antennas 72A-C, that is, in the alpha, beta, and gamma directions.

However, since the LPA redundancy circuit of the conventional base station RF board as described above has one additional LPA and a plurality of separate control switches to control the switching in case of LPA failure, it is necessary to manufacture the base station. In addition, the cost was significantly increased, and since the redundancy of separate LPAs and switches must be provided in the RF board, the space design of the RF board was also significantly degraded.

Therefore, the present invention is designed to solve the above-mentioned problems, and it is not necessary to provide a separate complicated redundancy circuit for the replacement of the failed LPA, so that the mobile communication base station can significantly reduce the manufacturing cost of the mobile communication base station. The purpose is to provide a linear power amplifier switching device.

Another object of the present invention is to provide a linear power amplifier switching device of a mobile communication base station that can be designed simply by the splitter and switching circuit configuration for LPA switching provided in the RF board, thereby significantly improving the spatial design of the mobile communication base station. It is.

1 is an explanatory diagram illustrating a LPA redundancy device of a conventional RF board.

2 is an explanatory diagram illustrating an LPA switching device of the present invention.

<Detailed Description of Codes>

1A-C: up / down converter section 2A-C: LPA

3A-C: Splitter 4A-C: Switch Section

5A-C: Antenna 6A-C: Filter

7: control unit 8: RF board

9: Digital card

The present invention for achieving the above object is a mobile communication base station system having a plurality of LPAs, a plurality of splitters connected to each output terminal of the plurality of LPAs and outputs two divided input signals, and the plurality of A plurality of switch units for switching outputs of a specific LPA by connecting two output signals separated at each output terminal of the splitter to each other as an input, and checking the failure of the LPA and controlling the switching of the plurality of switch units according to the result. It provides a linear power amplifier switching device of a mobile communication base station comprising a control unit.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

As shown in FIG. 2, the apparatus of the present invention outputs a CDMA transmission signal inputted from a digital card (not shown) of a base station to a frequency level of RF signal of a predetermined level or vice versa. A plurality of LPAs 2A-C connected to the converters 1A-C and output terminals of the plurality of up / down converters 1A-C, respectively, for amplifying the output RF signal with high power; A plurality of splitters 3A-C connected to each output terminal of the plurality of LPAs 2A-C for splitting and outputting the input signal into two, and two separated at each output terminal of the plurality of splitters 3A-C A plurality of switch units 4A-C for switching outputs of specific LPAs 2A-C by crossing output signals as inputs, and connected to output terminals of the plurality of LPAs 2A-C, respectively, for each LPA ( 2A-C) to filter the RF signals output from the antennas 5A-C Control the switching functions of the plurality of filters 6A-C and the plurality of switch units 4A-C that emit in multiple directions (alpha, beta, gamma), and the function of the RF board 8 in general. And a control unit 7 for controlling.

Here, the up / down converter units 1A-C of the base station as described above have at least three sectors (SECTOR) or more per multi-direction (alpha, beta, gamma) per base station.

Further, the connection of the switch parts 4A-C is, for example, one output of the splitter 3A is connected to one input of the switch part 4A, and the other output of the splitter 3A is connected to another switch part ( It is connected to one input of 4B). One output of the splitter 3B is connected to one input of the switch section 4B, and the other output of the splitter 3B is connected to one input of the other switch section 4C. In addition, one output of the splitter 3C is connected to one input of the switch section 4C, and the other output of the splitter 3C is connected to one input of the other switch section 4A.

Here, although the switch unit 4A-C is configured as an individual switch under the control of the control unit 7, it may be configured as one composite switch in which a plurality of switch contacts are combined.

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

First, a base station usually emits an RF signal for each sector in multiple directions, for example, at least three sectors (SECTOR) per alpha, beta, and gamma per base station. At this time, the plurality of up / down converters 1A-C of the RF board 8 of the base station receive the call signal in the low region from the digital card 9 at the lower stage, and uplink the frequency with the FR signal to connect it already. Output to the set LPA (2A-C) respectively. Here, the control unit 7 continues to check the state of each LPA (2A-C).

On the other hand, each of the LPA (2A-C) is amplified to each input RF signal to a high output and output to the corresponding splitter (3A-C) that is already set up. Then, each of the splitters 3A-C separates the input signal into two and outputs the signal to each corresponding switch unit 4A-C connected thereto.

That is, one of the two outputs of the splitter 3A is output to the switch section 4A and the other one to the switch section 4B. In addition, one of the two outputs of the splitter 3B outputs to the switch section 4B and the other to the switch section 4C. One of the two outputs of the splitter 3C outputs to the switch section 4C and the other to the switch section 4A.

Meanwhile, the respective RF signals passing through the switch parts 4A-C are output to the corresponding filters 6A-C currently connected to the switching contacts of the switch parts 4A-C.

Here, the switch unit 4A-C normally switches only one of the two inputs set therein and outputs it to the filters 6A-C.

Accordingly, each of the filters 6A-C filters the input RF signal and emits the RF signals in the directions set through the antennas 5A-C, that is, alpha, beta, and gamma directions.

Here, if the control unit 7 is checking the state of the plurality of LPA (2A-C), if any one of the failure, for example, if the LPA (2A) is broken, the control unit 7 is the switch unit 4A ) To switch from the connection contact of the splitter 3A connected to the LPA 2A to the connection contact to which the input of the other splitter 3C is connected. Then, the output of the failed LPA 2A is not switched to the switch unit 4A, but the output of the normal LPA 2C is switched and output to the filter 6A. Then, the filter 6A filters the RF signal input in a normal manner and emits the signal through the antenna 5A in the set direction.

Here, the description has been made on the assumption that the LPA has failed, but if any one of the remaining LPAs fails, the RF signal is normally processed by switching in the above manner.

As described above, the present invention includes a splitter for separating output signals of the LPA between the output terminals of the multiple LPAs and the multidirectional antennas provided on the RF board of the base station, and switching means connecting the outputs of the splitters to cross each other. By switching to a normal LPA through the switching means in the case of LPA failure, it is not necessary to have a separate complex redundancy circuit for switching the failed LPA has the advantage that can significantly reduce the manufacturing cost of the mobile communication base station.

In addition, according to the present invention, since the circuit configuration for switching the LPA included in the RF board can be easily designed only by the splitter and the switching, the spatial design of the mobile communication base station is also significantly improved.

Claims (2)

In the mobile communication base station system provided with a plurality of LPA, A plurality of splitters connected to each output terminal of the plurality of LPAs divide and output the input signal into two, and two output signals separated at each output terminal of the plurality of splitters are connected to each other as inputs to output an output of a specific LPA. And a plurality of switch units for switching and a controller for checking whether the LPA is broken and controlling switching of the plurality of switch units according to the result. The linear power amplifier switching device of claim 1, wherein the plurality of switch units comprise one composite switch.