KR20000015358A - Detector for transmission power in a testing device of a base station in a wireless local loop(will) system - Google Patents

Abstract

PURPOSE: A wireless local loop(WILL) system is provided to confirm, whether transmission power is appropriately outputted, by detecting the transmission power emitted through an antenna of a testing device in a wireless local loop(WILL). CONSTITUTION: A detector(55) for detecting transmission power in a testing device of a base station of a wireless local loop(WILL) system, attenuates the signal size by selecting one signal of three RF(Radio Frequency) signals, outputted from a RF controlling section according to a control signal of a digital processor. The detector(55) attenuates the signal size by generating a signal corresponding to a standard frequency of a cell, according to the control signal of the digital processor(52), and mixes the selected RF signal with the standard frequency signal, and outputs the RF signal to a serve cell unit. The detector(55) eliminates noises of the outputted signal and measures transmission power, emitted through an antenna of a base station to the each serve cell unit, by measuring the receiving field strength.

Description

Transmission power detector in base station test equipment of wireless subscriber network system

In the present invention, when configuring an unmanned base station of a wireless local loop (WLL) system, a base station test apparatus for testing a state of an unmanned base station detects transmission power radiated through a base station antenna. The present invention relates to a transmission power detector in a base station test apparatus of a WLL system.

In general, the WLL system is a system that forms a link using a wireless system instead of a wired line from a telephone station to a subscriber terminal. The WLL system can be configured in a shorter time than a conventional wired network and has an advantage of easy maintenance. It is expected to play an important role in building information infrastructure in the future.

The WLL system is largely composed of a subscriber station terminal, a base station for making a wireless link with a subscriber station terminal by wire, and a base station controller for controlling the base station.

On the other hand, when the base station is configured unattended in the WLL system of the configuration described above, the base station test apparatus for testing the base station alone and the state of the base station is necessary first of all, as shown in FIG. The test apparatus was further configured.

The present invention has been made in view of the above, and its purpose is to determine whether the transmit power of the unmanned base station is properly output by detecting the transmit power radiated through the base station antenna of the base station test apparatus in the unmanned base station of the WLL system. The present invention provides a transmission power detector in a base station test apparatus of a WLL system.

1 is a block diagram of a base station in a wireless subscriber network system equipped with a base station test apparatus according to the present invention;

2 is a block diagram of an apparatus for testing a base station of a wireless subscriber network system according to the present invention;

3 is a block diagram of a transmission power detector in a base station test apparatus of a wireless subscriber network system according to the present invention.

<Description of the symbols for the main parts of the drawings>

61: 3: 1 switch 62: the first variable attenuator

63: PLL section 64: second variable attenuator

65: Mixer 66: BPF

67: field strength measurement unit

The transmission power detector in the base station test apparatus of the WLL system of the present invention for achieving this purpose, selects one of the three sector-specific RF signal output from the RF control unit in accordance with the control signal of the digital processing unit to attenuate the signal size, Generate a signal corresponding to the reference frequency of the cell according to the control signal of the digital processing unit to reduce the size, and then mix the selected sector-specific RF signal with the reference frequency signal and output the sector-specific RF signal as a subcell unit signal. Then, by removing the noise of the output signal and measuring the received field strength, it is possible to measure the transmission power radiated through the base station antenna in each subcell unit.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the transmission power detector in the base station test apparatus of the WLL system according to the present invention.

1 is a block diagram of an unmanned base station of a WLL system having a base station test apparatus, the interface unit 10 matching with the base station controller and outputting a control signal, and connected to the interface unit 10 and a timing signal at each unit. The digital control unit 30 that operates by the synchronization unit 20 for outputting the signal and the timing signal output from the synchronization unit 20 to report the state of the base station to the host system according to the control signal of the interface unit 10. The RF control unit 40 converts the received RF signal into an IF signal according to the timing signal output from the synchronization unit 20, and outputs the converted RF signal to the digital control unit 30 and the control signal of the interface unit 10. The base station test unit 50 is configured to test the state of the base station by inputting the RF signal output from the RF control unit 40 according to.

As shown in FIG. 2, the base station test unit 50 inputs an RF signal from the RF control unit 40 to perform an RF signal processing function to detect an abnormality of a transmission / reception antenna, a base station transmission power detection, and a WLL terminal. RF test unit 51 to test the status of the base station by providing an RF signal path between the base station and the base station status, and information transmission and reception, and to test the power control induction and TPTL (Transmit Power Tracking Loop) functions. The WLL terminal connected between the RF test unit 51 and the digital processor 52 and the digital processor 52 which receives information through communication with the WLL terminal and analyzes the information and reports the state of the current base station to a higher system. It consists of 53.

The RF test unit 51 includes a transmission and reception power supply monitoring unit 54 for monitoring a transmission and reception power supply state, a transmission power detection unit 55 for detecting transmission power radiated through a base station antenna, and a virtual test for the actual test. A test line providing unit 56 which provides a line to enable a test between the WLL terminal 53 and the base station, a status display unit 57 which displays status result information of the base station output from each unit, and the digital processing unit ( And an information transmitter 58 for transmitting the request information according to the instruction of 52.

In the present invention relates to the transmission power detection unit 55, the configuration of the transmission power detection unit 55 according to the present invention, as shown in Figure 3, according to the control signal of the digital processing unit 52 RF control unit 40 A 3: 1 switch 61 for selecting one of the three sector-specific RF signals α, β, and γ output from the first sector, and a first amount for attenuating the magnitude of the RF signal selected by the 3: 1 switch 61. A PLL (Phase Locked Loop) unit 63 for generating a signal corresponding to a reference frequency of a cell according to the variable attenuator 62, the control signal of the digital processing unit 52, and the PLL unit 63 The second variable attenuator 64 attenuates the amplitude of the reference frequency signal generated by the predetermined amount, and the sector-specific RF signal passed through the first variable attenuator 62 and the reference frequency passed through the second variable attenuator 64. A mixer 65 for mixing the signals and outputting the sector-by-sector RF signal as a subcell unit signal, and A band pass filter 66 for filtering out the signal output from the aggregator 65 and removing noise, and the received electric field strength of the signal passing through the BPF 66 And a received electric field strength measuring unit 67 for measuring and outputting the result to the digital processing unit 52.

The operation of the transmission power detection unit 55 according to the present invention configured as described above is as follows.

The transmission power detector 55 measures the transmission power radiated through the base station antenna. In the present invention, the transmission power detection function is performed in the base station test apparatus based on three sectors / 1 frequency (Frequency Assignment). do.

First, the 3: 1 switch 61 of the transmission power detector 55 selects one of three sector-specific RF signals output from the RF controller 40 according to the control signal of the digital processor 52.

Subsequently, the first variable attenuator 62 attenuates a predetermined amount of the RF signal selected by the 3: 1 switch 61 and then outputs it to the mixer 65.

In addition, the PLL unit 63 generates a signal corresponding to the reference frequency of the cell and attenuates a certain amount through the second variable attenuator 64.

That is, in the present invention, in order to measure the transmission power of the base station in each sub-cell unit, the reference frequency of the cell through the PLL unit 63 to output the RF signals, which are mixed by sector, in the sub-cell unit using the reference frequency of the cell. To generate the corresponding signal.

Subsequently, the mixer 65 mixes the sector-specific RF signal passed through the first variable attenuator 62 and the reference frequency signal passed through the second variable attenuator 64 to convert the sector-specific RF signal into a subcell unit signal. Will output

Then, the output signal of the mixer 65 is filtered through the BPF 66 to remove noise, and the received field strength measuring unit 67 measures the received field strength of the signal passing through the BPF 66, and as a result, Is output to the digital processing unit 52.

In this way, it is possible to confirm whether the correct transmission power is properly radiated from the base station antenna through the measurement of the received electric field strength.

As described above, the present invention detects whether the transmission power of the unmanned base station is properly output and accurately detects the power supply output of the changing state of the CDMA (Code Division Multiple Access) method even when the base station is actually operated. This has the effect of being able to perform control.

Claims (1)

The base station test unit 50 for testing the state of the unmanned base station of the WLL system is a transmission and reception state monitoring unit 54, transmission power detection unit 55, test line providing unit 56, status display unit 57, information transmission and reception In the RF test section 51 consisting of a section 58, a digital processing section 52, and a WLL terminal 53, The transmission power detection unit 55 selects one of three sector-specific RF signals output from the RF control unit 40 according to the control signal of the digital processing unit 52, and 3: The first variable attenuator 62 reduces a predetermined amount of the RF signal selected by the first switch 61 and the PLL unit 63 generates a signal corresponding to the reference frequency of the cell according to the control signal of the digital processor 52. ), A second variable attenuator 64 that attenuates a magnitude of a reference frequency signal generated by the PLL unit 63, and a sector-specific RF signal and the second variable that have passed through the first variable attenuator 62. A mixer 65 for mixing the reference frequency signal passed through the attenuator 64 and outputting the sector-specific RF signal as a subcell unit signal, and a BPF for filtering out the signal output from the mixer 65 to remove noise. 66) and by measuring the received electric field strength of the signal passing through the BPF (66) A transmission power detector in a base station test apparatus for a wireless subscriber network system, characterized in that it comprises a receiving field strength measuring unit (67) output to a digital processing unit (52).