KR19990061553A - Power change monitoring device of code division multiple access system - Google Patents

Abstract

The present invention relates to a power change monitoring apparatus of a code division multiple access system, and is generated due to the interference of FA / Sector of adjacent cells in the PVMA calibration due to the influence on the main path. In addition, the measurement error is improved, and the cost and size of the system are increased as the number of PVMA boards increases due to FA expansion.

As described above, the present invention provides a plurality of attenuators each of which receives input power from a front end for a plurality of signals and attenuates them to a predetermined level; A switching unit which selects and outputs one sector signal according to a control signal among the sector signals output from the attenuator; A mixer which receives the final transmission output signal selected by the switching unit and converts the frequency into an intermediate frequency signal; Receive signal strength voltage measuring means for detecting the intermediate frequency signal output from the mixer by converting only the desired signal through the surface acoustic wave filter to the received signal strength voltage; RF signal processing means for adjusting the level of the signal output from the received signal strength voltage measuring means according to the detection result of the ambient temperature.

Description

The apparatus for Power Variation Monitoring Assembly of CDMA

The present invention relates to a Code Division Multi Access (CDMA) power change monitoring assembly (hereinafter abbreviated as PVMA) in a base station, and in particular, FA of another adjacent cell during PVMA tracking. Improves measurement error caused by Coupling Power affecting the Main Path, and also improves the cost and the size of the system as the number of PVMA boards increases due to FA expansion It relates to a power change monitoring device of a code division multiple access system.

In the conventional CDMA PVMA, as shown in FIG. 1, a PVMA capable of accommodating 1FA / 3Sectors in one card converts the final output signal of the transmission path into a received signal strength (RSSI) voltage to monitor the change in the final transmission output level. It provides the ability to do so. The signal detection units 61 to 63 which transmit / receive from each of the FA1 ALPA PATH FA1 GAMMA PATH 10, 20, 30 detect whether the signal is normally transmitted / received.

Each signal received through the antenna passes through a filter (DUFA-8) and is input to each path 10 to 30. The signals input to each path 10 to 30 are attenuator 31, mixer 32, SAW filter 33, first amplifier 34, second attenuator 35, second amplifier 36 and RSSI. It is configured to pass through 37.

A PLL Synthesizer 41 receives a reference 10 MHz from a Global Position System (GPS) and generates 7.2 MHz local signals, local signals for FA1 and FA2. The signal generated by the PLL synthesizer 41 is amplified by a predetermined level in the amplifier 42 and separated by a 4 way divider 43, and then the corresponding signal is input to the mixer 131. The signal output from the mixer 131 is band filtered through the SAW filter 33.

Here, the mixer 32 receives the final transmission output signal and converts the frequency into a 120 MHz intermediate frequency (IF) signal. The reason for the frequency conversion into the intermediate frequency signal is that there are several signals with different FAs in the transmission frequency band. This is because the RSSI voltage of the desired signal can be measured separately.

The RSSI 37 also determines the current transmission output level by calibrating the RSSI voltage according to the change of the final transmission output signal. The RSSI voltage measurement should be within 0 to 5 V as the change in the transmit output signal occurs.

The temperature detection sensor 51 detects the current temperature of the PVMA-8 by using a 3-wire method and inputs it to the RF signal processing unit (RFPA) 54.

The EEPROM 52 stores the result of measuring the RSSI voltage according to the change of the level of the input signal for each temperature while increasing the temperature at 10 ° C intervals from 0 ° C to 60 ° C. Since the result data is basic data measuring the final output power of the transmission path, reliability of the data is required.

However, in the CDMA PVMA system according to the related art, measurement error occurs because the coupling power of another adjacent FA / Sector affects the main path, and the number of boards is increased when the FA is expanded with a limited board size. There was a problem that constitutes an inefficient circuit to increase the.

Accordingly, the present invention is generated because the interference of FA / Sector of other cells adjacent to the main path affects the main path during PVMA calibration in order to improve the problems according to the prior art. It is an object of the present invention to provide a power change monitoring device of a code division multiple access system that improves measurement error and improves the cost of increasing the number of PVMA boards and the size of the system.

1 is a block diagram of a power change monitoring apparatus according to the prior art,

2 is a block diagram of a power change monitoring apparatus of a code division multiple access system according to an exemplary embodiment of the present invention.

Explanation of symbols for the main parts of the drawings

101-103: front end 111-113, 134: attenuator

120: switching unit 131: mixer

132: SAW filter 133, 135: amplifier

136: RSSI voltage detector

CDMA PVMA device for achieving the above object of the present invention comprises: each attenuator receiving the input power from the front end (Front End) for a plurality of signals attenuated to a predetermined level; A switching unit for selectively outputting one sector signal according to a control signal among the sector signals output from the attenuator; A mixer configured to receive the final transmission output signal selected by the switching unit and convert the frequency into an intermediate frequency signal; Received signal strength voltage measuring means for separating and detecting only the desired signal through the surface acoustic wave filter and converting the intermediate frequency signal output from the mixer into a received signal strength voltage; RF signal processing means for adjusting the level of the signal output from the received signal strength voltage measuring means according to the detection result of the ambient temperature.

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

2 is a block diagram of a CDMA PVMA device according to an exemplary embodiment of the present invention. As shown in FIG. 2, the input power is attenuated to a predetermined level by receiving input power from the front ends 101 to 103 for a plurality of signals. Respective attenuators 111 to 113; A switching unit 120 for selectively outputting one sector signal according to a control signal among the sector signals output from the attenuators 111 to 113; A mixer 131 for receiving the final transmission output signal selected by the switching unit 120 and converting the frequency into an intermediate frequency (IF) signal; A received signal strength voltage detector 136 for converting the intermediate frequency IF signal output from the mixer 131 into a RSSI voltage by separating only a desired signal through a surface acoustic wave filter 132; The RF signal processor 54 adjusts the level of the signal output from the received signal strength voltage detector 136 according to the detection result of the ambient temperature. Hereinafter, the same reference numerals are given to the same parts as in the related art. Detailed description will be omitted.

If described in more detail with reference to Figure 2 the operation of the present invention configured as follows.

In the present invention, three sector signals are applied to the switching unit 120 by receiving input power from three front ends 101 to 103, and select only one sector signal according to a control signal. The selected sector signal removes the interference signal of the adjacent signal by correcting the PVMA.

To this end, the PLL synthesizer 41 receives a reference frequency of 10 MHz from the GPS, generates a 7.2 MHz local signal, a local signal for FA1 and FA2, amplifies a predetermined level through the amplifier 42, and then passes the 'FA1' through the 4-way separator 43. It is divided into ALPHA LOCAL, FA1 BETA LOCAL, FA GAMMA LOCAL, and FA1 LOCAL SAMPLE 'and output to the corresponding path.

Here, referring to the FA1 ALPHA LOCAL path 130, the corresponding signal is output to the mixer 131 to measure the RSSI voltage.

That is, the mixer 131 receives the final transmission output signal, converts the frequency into a 120 MHz intermediate frequency signal. The reason for the frequency conversion to the intermediate frequency signal is that since there are several signals with different FAs in the transmission frequency band, in order to extract only the desired signal, the frequency is converted into the intermediate frequency signal and passed through the SAKI filter having good SKIRT characteristics to separate only the desired signal. This is because the RSSI voltage of the desired signal can be measured.

The intermediate frequency signal detected by band filtering by the SAW filter 132 is input to the RSSI voltage detector 136 through the amplifier 133, the attenuator 134, and the amplifier 135.

The RSSI voltage detector 136 measures the RSSI voltage according to the change of the final transmission output signal and thus determines the current transmission output level. RSSI voltage measurements are designed to be within 0 to 5V, depending on the transmit output signal.

The power level of the base station is about 2 to 3 dB per cell due to the external environment, which should be kept constant at all times. To this end, the temperature sensor 51 detects the ambient temperature at regular intervals, and reads the current temperature of the PVMA-8 using the 3 WIRE method and provides it to the RF signal processor 54.

The EEPROM 52 stores the result of measuring the RSSI voltage as the level of the input signal changes for each temperature while increasing the temperature from 0 ° C to 60 ° C at 10 ° C intervals. Since this calibration data is the basic data measuring the final output power of the transmission path, reliability of the data is required.

Meanwhile, the signal detector 140 determines whether an error has occurred according to a result of detecting the signal output through the RSSI voltage detector 136 to alert the user.

As described above, the present invention improves the measurement error caused by the interference of FA / Sector of other adjacent cells during the PVMA calibration, which affects the main path, and also increases the cost and cost of increasing the number of PVMA boards due to FA expansion. This has the effect of improving the size of the system.

Claims (2)

Attenuators each of which receives input power from a front end for a plurality of signals and attenuates them to a predetermined level; A switching unit for selectively outputting one sector signal according to a control signal among the sector signals output from the attenuator; A mixer configured to receive the final transmission output signal selected by the switching unit and convert the frequency into an intermediate frequency signal; Received signal strength voltage measuring means for separating and detecting only the desired signal through the surface acoustic wave filter and converting the intermediate frequency signal output from the mixer into a received signal strength voltage; And RF signal processing means for adjusting the level of the signal output from the received signal strength voltage measuring means according to the detection result of the ambient temperature. The method of claim 1, Receiving a reference signal from the satellite control system, down-converting and generating a plurality of local signals and transmitting to the mixer, the phase change loop synthesizer, characterized in that the power change monitoring device of the code division multiple access system.