KR20000055931A - Device and method for measuring automatically inverse direction efficiency between cellular phone and basestation transceiver subsystem in cdma system - Google Patents

Abstract

PURPOSE: A method for automatically measuring backward performance between a terminal and a base station in a code division multiple access(CDMA) system, is provided to reduce a measuring time of the backward performance and to perform a convenient measure, by automatically measuring the backward performance from the terminal to the base station to inform an operator of the measured value. And the method is provided for the operator to correctly decide backward performance, as a high-performance computer analyzes a result value of the backward performance and displays the value for the operator. CONSTITUTION: A method for automatically measuring backward performance between a terminal and a base station in a code division multiple access(CDMA) system, comprises the steps of: deciding whether a backward performance measuring menu selected by an operator is a terminal access probe acquisition test; if so, receiving a noise generator mode, a range of an Eb/No value and number of times for Markov test calls from a main processor; calculating a value of number of times for a test execution by the main processor with the Eb/No value range and the number of times for Markov test calls, and initializing a test coefficient; initializing a system to execute the terminal access probe acquisition test; demanding transmission of Markov test calls to the terminal by an RS-422 controller of the base station; deciding the noise generator mode by the main processor; if the mode is an Eb/No mode, setting an Markov test calls environment corresponding to the Eb/No mode by the main processor; transmitting the Markov test calls, of which an environment is decided, to the base station by the terminal; cutting off transmission of Markov test calls by the RS-422 controller; executing a terminal access probe acquisition test between the terminal and the base station, and storing the result value in a log file by an RS-232 controller of the base station; comparing a value of testing number of times and the test coefficient to decide whether to be equal by the main processor; if not, increasing a test coefficient by one and progressing to the step of demanding transmission of Markov test calls, and if equal, displaying the result of the terminal access probe acquisition to the operator by the main processor.

Description

DEVICE AND METHOD FOR MEASURING AUTOMATICALLY INVERSE DIRECTION EFFICIENCY BETWEEN CELLULAR PHONE AND BASESTATION TRANSCEIVER SUBSYSTEM IN CDMA SYSTEM}

The present invention relates to an apparatus and method for measuring backward performance between terminals / base stations in a code division multiple access (CDMA) system, and in particular, to automatically measure the backward performance from the terminal to the base station to the operator. An apparatus and method for automatically measuring reverse performance between terminals / base stations in a CDMA system for displaying a value.

In the conventional CDMA system, the terminal / base station backward performance measurement method, when the CDMA reverse performance measurement, the operator manually connects a plurality of wired equipment and protocol equipment required for the test. Then, the operator enters the CDMA Reverse Performance Measurement Menu and various necessary data through the terminal, and manually repeats the test several times. Then, the operator compares and analyzes the test progress value and the result value as many times as the reverse measurement test is performed, and records the result in his test note. The operator then analyzes the test results recorded by the operator to determine the reverse performance between the terminal and the base station.

However, in the above-described method for measuring backward performance between terminals and base stations in the conventional CDMA system, the operator must manually measure the backward performance from the terminal to the base station direction and then calculate a result value. Not only did it take a long time, but the measurement process was complicated and inconvenient.

In addition, in the above-described conventional CDMA system, the terminal / base station backward performance measurement method, since the operator manually measures the reverse performance from the terminal to the base station direction, and then calculates and analyzes the result value, thus, the terminal and the base station. There was a problem that it is impossible to accurately determine the reverse performance between the two.

Accordingly, the present invention has been made to solve the conventional problems as described above, an object of the present invention is to reduce the backward performance measurement time from the terminal to the base station direction, and provides the operator with the convenience of measurement due to automated measurement In addition, the present invention provides an apparatus and method for automatic measurement of reverse performance between terminals / base stations in a CDMA system that can calculate and display accurate measurement results.

In order to achieve the above object, an apparatus for automatically measuring reverse performance between terminals / base stations in a CDMA system of the present invention includes: a terminal for transmitting a predetermined number of access messages and a Markov test call when measuring backward performance; It consists of a signal attenuator, noise generator, fading emulator, and spectrum analyzer to control fading, additional noise, and signal attenuation on the Markov test call so that the Markov test call transmitted from the terminal is transmitted in the same situation as the call during actual call processing. Measuring equipment; A signal distributor; In the apparatus for measuring the backward performance from the terminal to the base station in a CDMA system consisting of a base station transmitting and receiving a Markov test call and an access message transmitted from the terminal,

A terminal for outputting the selected data when the operator selects a backward performance measurement menu, a noise generator mode, an Eb / No value range, and a Markov test call number, and displays a reverse performance measurement result to the operator; After receiving the backward performance measurement menu signal, the noise generator mode signal, the Eb / No value range signal, and the Markov test call number signal outputted from the terminal, totally control the reverse performance measurement operation corresponding to the reverse performance measurement menu selected by the operator. And then, the main processor for displaying the final result of the backward performance test to the operator; A log file for storing successive backward performance measurement results; The terminal access probe acquisition test control signal output from the main processor is input, and the base station is controlled to perform the terminal access probe acquisition test, and then the successful access probe output from the base station is received and the test result is recorded in the log file. A base station RS-232 control unit for storing in the base station; A base station RS-422 control unit which outputs a Markov test call call request signal to the base station, receives a plurality of Markov frame error rates output from the base station, and stores the test result values in the log file; An analysis module for reading and analyzing a backward performance test result value stored in the log file, and outputting a final result of a backward performance test to the main processor; A terminal controller which receives a control signal output from the main processor and transmits a terminal configuration parameter to the terminal and controls an access message transmission operation of the terminal; It is characterized by consisting of a measurement equipment control unit for receiving the control signal output from the main processor to control the test call environment setting operation of the measurement equipment.

In addition, the terminal access probe acquisition test method of the automatic measurement method between the terminal / base station reverse performance in the CDMA system according to an embodiment of the present invention,

A first step of determining whether the reverse performance measurement menu selected by the operator is a terminal access probe acquisition test; A second step of receiving, by the main processor, a noise generator mode, an Eb / No value range, and a Markov test call number input by an operator if the backward performance measurement menu selected by the operator in the first step is a terminal access probe acquisition test; A third step of the main processor calculating a test execution count value using an Eb / No value range and a Markov test call count and initializing test coefficients; A fourth step of performing a system initialization operation for performing a terminal access probe acquisition test; A fifth step of requesting transmission of a Markov test call from the base station RS-422 control unit to the terminal; A sixth step of determining, by the main processor, a noise generator mode input by an operator; A seventh step in which the main processor performs a Markov test call configuration setting operation corresponding to the Eb / No mode if the noise generator mode input by the operator in the sixth step is an Eb / No mode; An eighth step of the terminal transmitting a Markov test call whose environment is determined to the base station; A ninth step in which the base station RS-422 controller blocks transmission of a Markov test call; A tenth step of performing, by the base station RS-232 controller, a terminal access probe acquisition test between the terminal and the base station, and storing the result in the log file; An eleventh step, wherein the main processor compares a test execution count value with a test coefficient to determine whether the main processor is the same; If the test execution frequency value and the test coefficient are not the same in the eleventh step, the test coefficient is increased to " 1 ", and then the process proceeds to the fifth step. And a twelfth step of displaying the acquired test result to the operator.

On the other hand, in the CDMA system according to an embodiment of the present invention, the reverse traffic performance test method under additional noise in the automatic reverse performance measurement between the terminal / base station,

A first step of determining whether the reverse performance measurement menu selected by the operator is a reverse traffic performance test under additional noise; If the backward performance measurement menu selected by the operator in the first step is a backward traffic performance test under additional noise, the main processor receives a noise generator mode, an Eb / No value range, and a Markov test call number input by the operator; Step; A third 'step of the main processor calculating a test execution count value using an Eb / No value range and a Markov test call count and initializing test coefficients; A fourth 'step of performing a system initialization operation to perform a reverse traffic performance test under additional noise; A fifth step of requesting transmission of a Markov test call from the base station RS-422 control unit to the terminal; A sixth step of determining, by the main processor, a noise generator mode input by an operator; A seventh step in which the main processor performs a Markov test call configuration setting operation corresponding to the Eb / No mode if the noise generator mode input by the operator in the sixth step is an Eb / No mode; An eighth step of transmitting, by the terminal, a plurality of Markov test calls whose environment is determined to the base station; A ninth step of performing, by the base station RS-422 control unit, a reverse traffic performance test under the additional noise between the terminal and the base station, and storing the result in the log file; A tenth step in which the main processor compares a test execution count value with a test coefficient to determine whether the main processor is the same; If the test execution count value and the test coefficient are not equal to each other in the tenth step, the test coefficient is increased to "1" and then proceeds to the fifth 'step. And an 11 'step of displaying the results of the reverse traffic performance test under the noise to the operator.

Further, in the CDMA system according to an embodiment of the present invention, among the method for automatically measuring the reverse performance between terminals and base stations, the reverse traffic performance test method under multipath fading includes:

A first " step of determining whether the reverse performance measurement menu selected by the operator is a reverse traffic performance test under multipath fading; and a reverse traffic performance test under multipath fading with the reverse performance measurement menu selected by the operator in the first " And a second " step of receiving, by the main processor, a noise generator mode, an Eb / No value range, and a Markov test call number input by an operator; the main processor tests using the Eb / No value range and the Markov test call number. A third "step of initializing the test coefficients while calculating the execution count value; Performing a system initialization operation for performing reverse traffic performance testing under multipath fading; and outputting, to the fading emulator, a multipath fading set value for determining the multifading pass characteristics of a Markov test call by the instrumentation control unit. A fifth "step; A sixth " step of requesting transmission of a Markov test call from the base station RS-422 control unit to the terminal; a seventh " step of the main processor determining a noise generator mode input by an operator; An eighth " step of performing, by the main processor, a Markov test call configuration setting operation corresponding to the Eb / No mode if the noise generator mode input by the operator in the seventh " step is Eb / No mode; A ninth step of setting a multi fading pass characteristic in a Markov test call through a multipath fading set value inputted by the fading emulator; and a tenth " for transmitting the plurality of Markov frames whose environment is determined to the base station by the terminal; Steps; An eleventh " step of performing, by the base station RS-422 controller, the reverse traffic performance test under the multipath fading between the terminal and the base station, and storing the result in the log file; A twelfth " step of comparing the test coefficients to determine whether they are the same; If the test execution count value and the test coefficient are not equal to each other in the twelfth step, the test coefficient is increased to "1", and then the process proceeds to the fifth "step. And a 13 " step of displaying the results of the reverse traffic performance test under pass fading to the operator.

1 is a station-to-base station station in a CDMA system according to an embodiment of the present invention.

Functional block diagram showing the automatic direction measurement device,

2 is a station / base station between CDMA systems according to an embodiment of the present invention;

Terminal Access Probe Acquisition Test Method in Automatic Direction Measurement Method

Action flow chart showing the law,

3 is a fourth step in a terminal access probe acquisition test method according to FIG.

An operation flowchart specifically showing (S4),

4 is a seventh step in the terminal access probe acquisition test method according to FIG.

An operation flowchart specifically showing (S7),

5 is a tenth step in the terminal access probe acquisition test method according to FIG.

An operation flowchart specifically showing (S10),

6 is a thirteenth step in the terminal access probe acquisition test method according to FIG.

An operation flowchart specifically showing (S13),

7 is a station / base station between CDMA systems according to an embodiment of the present invention.

Reverse traffic performance under additional noise in automatic directional performance measurement

Flow chart showing the functional test method,

8 is a reverse traffic performance test method under additional noise according to FIG.

An operation flowchart specifically showing the fourth step S4 ',

9 is a reverse traffic performance test method under additional noise according to FIG.

An operation flowchart specifically showing the seventh step S7 ',

10 is a reverse traffic performance test method under additional noise according to FIG.

An operation flowchart specifically showing a ninth step S9 ',

11 is a reverse traffic performance test method under additional noise according to FIG.

An operation flowchart specifically showing a twelfth step (S12 '),

12 is a diagram illustrating a terminal / base station between CDMA systems according to an embodiment of the present invention.

Reverse direction under multipass fading in automatic reverse performance measurement

Operation flow chart showing traffic performance test method,

FIG. 13 illustrates a reverse traffic performance test under multipath fading according to FIG. 12. FIG.

An operational flow chart specifically showing the fourth " step S4 "

FIG. 14 is a test of reverse traffic performance under multipath fading according to FIG.

An operational flow chart specifically showing the eighth " step S8 "

FIG. 15 is a test of reverse traffic performance under multipath fading according to FIG.

An operational flow chart specifically showing the eleventh " step S11 "

FIG. 16 is a test of reverse traffic performance under multipath fading according to FIG.

The operation flow chart specifically showing the 14th step "S14" in the law

All.

<Explanation of symbols for main parts of drawing>

10: terminal 20: measurement equipment

21: signal attenuator 22: noise generator

23: Fading Emulator 24: Spectrum Analyzer

30: signal splitter 40: base station

100: terminal 200: main processor

300: log file 400: base station RS-232 control unit

410: RS-232 process unit 420: RS-232 interface unit

500: base station RS-422 control unit 510: RS-422 process unit

520: RS-422 interface 600: analysis module

700: terminal controller 710: terminal processor

720: terminal interface unit 800: measurement equipment control unit

810: measuring equipment process unit 820: measuring equipment interface unit

Hereinafter, an apparatus and method for automatically measuring reverse performance between terminals / base stations in a CDMA system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a functional block diagram of an apparatus for automatically measuring reverse performance between terminals and base stations in a CDMA system according to an embodiment of the present invention, and automatically measures backward performance between terminals and base stations in a CDMA system according to an embodiment of the present invention. The apparatus includes a terminal 100, a main processor 200, a log file 300, a base station RS-232 control unit 400, a base station RS-422 422) the control unit 500, the analysis module 600, the terminal control unit 700 and the measurement equipment control unit (800).

The terminal 100 allows an operator to perform a backward performance measurement menu, a noise generator mode, a bit energy to noise power spectral density ratio (hereinafter referred to as Eb / No), a range of values, and a number of Markov test calls. If it is selected and outputs the selected data to the main processor 200, and displays the reverse performance measurement results to the operator (Display).

Meanwhile, the main processor 200 receives the backward performance measurement menu signal, the noise generator mode signal, the Eb / No value range signal, and the Markov test call count signal output from the terminal 100, and then selects the backward performance selected by the operator. It controls the reverse performance measurement operation corresponding to the measurement menu as a whole, and then outputs the final result of the reverse performance test to the terminal 100.

In addition, the log file 300 is a memory for storing the results of the successive backward performance measurement output from the base station RS-232 control unit 400 and the base station RS-422 control unit 500.

The base station RS-232 controller 400 receives a terminal access probe acquisition test control signal output from the main processor 200 and controls the base station 40 to perform a terminal access probe acquisition test. After receiving the successful access probe output from the base station 40 serves to store the test result value in the log file 300, RS-232 process unit (410) and RS-232 interface ( Interface) 420.

Meanwhile, the RS-232 processor 410 mounted in the base station RS-232 control unit 400 receives a mobile station access probe acquisition control signal output from the main processor 200. A terminal access probe acquisition test request signal is output to the base station 40, and a plurality of successful access probes output from the base station 40 are received and stored in the log file 300.

The RS-232 interface unit 420 mounted in the base station RS-232 control unit 400 performs a data interface operation between the base station 40 and the RS-232 processor unit 410.

In addition, the base station RS-422 control unit 500 outputs a Markov test call call request signal to the base station 40, and determines the transmission time of the Markov test call transmitted from the terminal 10 to the base station 40. Role.

The base station RS-422 control unit 500 receives frame error rates of a plurality of Markov test calls output from the base station 40 and stores the test result values in the log file 300. It is composed of a 422 processor 510 and an RS-422 interface 520.

On the other hand, the RS-422 processor 510 mounted in the base station RS-422 control unit 500 outputs a Markov test call call request signal to the base station 40, and a plurality of Markovs output from the base station 40. It receives a frame error rate of a test call and stores it in the log file 300.

In addition, the RS-422 interface unit 520 mounted in the base station RS-422 control unit 500 performs a data interface operation between the base station 40 and the RS-422 processor unit 510.

Meanwhile, the analysis module 600 reads backward performance test result values stored in the log file 300 and analyzes them, and outputs test data and final result values of the reverse performance test to the main processor 200. Do it.

In addition, the terminal controller 700 receives a control signal output from the main processor 200 and transmits a terminal configuration parameter to the terminal 10, and controls an access message transmission operation of the terminal 10. It is composed of a terminal processor 710 and the terminal interface unit 720.

Meanwhile, the terminal processor 710 mounted in the terminal controller 700 receives a control signal output from the main processor 200 and transmits a terminal configuration parameter to the terminal 10, while transmitting an access message. It outputs an access message transmission control signal for controlling the operation to the terminal 100, and outputs a power control signal for setting the transmission power control of the terminal 10 to the terminal 10.

In addition, the terminal interface 720 mounted in the terminal controller 700 performs a data interface operation between the terminal 10 and the terminal processor 710.

In addition, the measurement equipment controller 800 receives a control signal output from the main processor 200 and controls a test call environment setting operation of the measurement equipment unit 20, and the measurement equipment processor 810. ) And the measurement equipment interface unit 820.

On the other hand, the measurement equipment processor 810 mounted in the measurement equipment control unit 800 receives the control signal output from the main processor 200, the fading control signal, the additional noise control signal to the measurement equipment unit 20 And a signal attenuation control signal.

In addition, the measurement instrument interface 820 mounted in the measurement instrument controller 800 performs a data interface operation between the measurement instrument unit 20 and the measurement instrument processor 810.

Next, a method for automatically measuring backward performance between terminals and base stations in a CDMA system according to an embodiment of the present invention using an apparatus for automatically measuring backward performance between terminals and base stations in a CDMA system having the above configuration will be described. .

FIG. 2 is an operation flowchart showing a terminal access probe acquisition test method in a method for automatically measuring backward performance between terminals and base stations in a CDMA system according to an embodiment of the present invention, and FIG. 3 is a terminal access probe acquisition method according to FIG. 4 is an operational flowchart specifically showing the fourth step S4 in the test method, and FIG. 4 is an operational flowchart specifically showing the seventh step S7 in the terminal access probe acquisition test method according to FIG. 2.

5 is an operation flowchart specifically illustrating a tenth step S10 in the terminal access probe acquisition test method according to FIG. 2, and FIG. 6 is a thirteenth step in the terminal access probe acquisition test method according to FIG. 2. ) Is an operation flow chart that specifically shows.

FIG. 7 is an operation flowchart illustrating a method for testing reverse traffic performance under additional noise in a method for automatically measuring reverse performance between terminals and base stations in a CDMA system according to an embodiment of the present invention, and FIG. 8 is an additional flowchart according to FIG. FIG. 9 is a flowchart illustrating the fourth step S4 'in the reverse traffic performance test method under noise. FIG. 9 illustrates the seventh step S7' in the reverse traffic performance test method under additional noise according to FIG. Specifically, the operation flowchart is shown.

FIG. 10 is an operational flowchart specifically showing the ninth step S9 'in the reverse traffic performance test method under additional noise according to FIG. 5, and FIG. 11 is a reverse traffic performance test method under additional noise according to FIG. Is an operational flowchart specifically showing a twelfth step (S12 ').

12 is an operation flowchart illustrating a reverse traffic performance test method under multipath fading among the automatic terminal / base station reverse performance measurement methods in the CDMA system according to an embodiment of the present invention, and FIG. FIG. 14 is an operational flowchart showing the fourth "step S4" in the reverse traffic performance test method under multipath fading. FIG. 14 shows the eighth "step (S8) in the reverse traffic performance test method under multipath fading according to FIG. An operation flowchart specifically showing ").

FIG. 15 is an operational flowchart specifically showing an eleventh " step S11 " in the reverse traffic performance test method under multipath fading according to FIG. 12, and FIG. 16 is a reverse traffic performance under multipath fading according to FIG. In the test method, as an operation flowchart specifically showing the 14 " step (S14 "), S denotes a step (STEP).

First, a method of obtaining a terminal access probe in a method for automatically measuring backward performance between terminals / base stations in a CDMA system according to an embodiment of the present invention will be described with reference to FIGS. 2, 3, 4, 5, and 6. Shall be.

Initially, the operator selects through the terminal 100 a backward performance measurement menu, a noise generator mode, an Eb / No value range and a Markov test call count. Then, the terminal 100 outputs the backward performance measurement menu signal selected by the operator to the main processor 200. Subsequently, the main processor 200 determines whether the backward performance measurement menu selected by the operator is a terminal access probe acquisition test (S1).

In this case, if the backward performance measurement menu selected by the operator is a terminal access probe acquisition test (YES), the main processor 200 performs a noise generator mode, an Eb / No value range, and a Markov test input by the operator through the terminal 100. The number of calls is input (S2).

Meanwhile, the main processor 200 calculates a test execution count value using the Eb / No value range and the Markov test call count input through the terminal 100 and initializes test coefficients (S3).

Then, the main processor 200 performs a system initialization operation for performing a terminal access probe acquisition test (S4).

In this case, the system initialization operation S4 for the terminal access probe acquisition test described above will be described in detail with reference to FIG. 3. First, the main processor 200 initializes the Eb / No value range loop and the Markov test call count loop (S4-1). In addition, the main processor 200 turns off the transmission power control function of the terminal 10 (S4-2).

In addition, the RS-422 processor 510 mounted in the base station RS-422 controller 500 outputs a Markov test call transmission request signal to the base station 40 via the RS-422 interface 520. Then, the base station 40 requests the Markov test call transmission to the terminal 10 (S5).

The main processor S200 determines whether the noise generator mode input by the operator is an Eb / No mode or a noise generator mode (S6).

In this case, if the noise generator mode input by the operator in the sixth step S6 is an Eb / No mode, the main processor 200 performs a Markov test call environment setting operation corresponding to the Eb / No mode (S7). .

At this time, the environment setting operation (S7) of the Markov test call corresponding to the Eb / No mode described above will be described in detail with reference to FIG. First, the noise generator 22 of the measurement equipment unit 20 receives a control signal output from the measurement equipment processor 810 and measures a transmission power value of the terminal 10 (S7-1). . Subsequently, the noise generator 22 calculates additional noise of the Markov test call based on the transmission power value measured by the noise generator and the Eb / No value input by the operator (S7-2). In addition, the noise generator 22 sets additional noise to the Markov test call transmitted from the terminal 10 (S7-3). On the other hand, the signal attenuator 21 attenuates the level of the Markov test call transmitted from the terminal 10 (S7-4). Therefore, the Markov test call transmitted from the terminal 10 is changed to the same environment as the call processing signal of the actual situation.

Then, the terminal 10 transmits the Markov test call whose environment is determined to the base station 40 (S8).

In addition, when the base station 40 receives the Markov test call, the base station RS-422 control unit 500 outputs a Markov test call transmission blocking control signal to the base station 40, and the base station 40 transmits the base station 40. After receiving the Markov test call transmission block control signal output from the RS-422 controller 500, the Markov test call transmission operation of the terminal 10 is blocked (S9). Thus, the test preparation process for the terminal access probe acquisition test is completed through the above operation process.

Meanwhile, the RS-232 process unit 410 mounted in the base station RS-232 control unit 400 performs a terminal access probe acquisition test between the terminal 10 and the base station 40, and then logs the resultant value. It is stored in the file 300 (S10).

In this case, the terminal access probe acquisition test operation S10 performed by the RS-232 processor 410 will be described in detail with reference to FIG. 5 as follows. First, the RS-232 processor 410 outputs a terminal access probe acquisition test request signal to the base station 40 (S10-1). Meanwhile, the terminal processor 710 mounted in the terminal controller 700 outputs an access message transmission control signal to the terminal 10 (S10-2). Then, the terminal 10 transmits the set number of access messages to the base station 40 (S10-3), and the base station 40 receives a plurality of access messages transmitted from the terminal 10, The successful access fruit part is output to the RS-232 processor 410 (S10-4). Subsequently, the RS-232 processor 410 receives a plurality of successful access fruits that have passed through the RS-232 interface 420 and stores them in the log file 300 (S10-5). Then, the RS-232 processor 410 mounted in the base station RS-232 control unit 400 outputs a terminal access probe acquisition test stop request signal to the base station 40, and the base station 40 transmits the signal. Stop the terminal access probe acquisition test by receiving the (S10-6). Meanwhile, the analysis module 600 reads and analyzes the successful access probe stored in the log file 300 and outputs the terminal access probe acquisition test result value to the main processor 200 (S10-7).

In addition, the main processor 200 compares the test execution count value calculated in the third step S3 with the test coefficients to determine whether they are the same (S11).

At this time, if the test execution count value and the test coefficient are not equal to each other in the eleventh step S11 (NO), the main processor 200 increases the test coefficient by "1" and then moves to the fifth step S5. Proceed and perform the terminal access probe acquisition test again. However, if the test execution frequency value and the test coefficient are the same in the eleventh step S11 (YES), the main processor 200 displays a display control signal for displaying the terminal access probe acquisition test result to the operator. Output to 100). Then, the terminal 100 receives the display control signal output from the main processor 200 and displays the number of successes of access, which is a result of the terminal access probe acquisition test, to the operator (S12).

Therefore, the operator determines the reverse performance between the terminal 10 and the base station 40 while looking at the number of successful accesses displayed through the terminal 100.

Meanwhile, in the sixth step S6, if the noise generator mode input by the operator is the noise generator mode, the main processor 200 performs the Markov test call environment setting operation corresponding to the noise generator mode and then performs the eighth operation. The flow advances to step S8 (S13).

In this case, the environment setting operation S13 of the Markov test arc corresponding to the noise generator mode described above will be described in detail with reference to FIG. 6. First, the spectrum analyzer 24 of the measurement equipment unit 20 receives a control signal output from the measurement equipment processor 810 and measures a transmission power value of the terminal 10 (S13-1). . Subsequently, the noise generator 22 calculates additional noise of the Markov test call based on the transmission power value measured by the spectrum analyzer 24 and the Eb / No value input by the operator (S13-2). In addition, the noise generator 22 sets additional noise to the Markov test call transmitted from the terminal 10 (S13-3). On the other hand, the signal attenuator 21 attenuates the level of the Markov test call transmitted from the terminal 10 by an amount calculated to match the reception level of the base station 40 (S13-4). Therefore, the Markov test call transmitted from the terminal 10 is changed to the same environment as the call processing signal of the actual situation.

On the other hand, in the CDMA system according to an embodiment of the present invention in the reverse performance between the terminal / base station automatic measurement method for the reverse traffic performance test method under the additional noise with reference to Figure 7, 8, 9, 10, 11 Let's explain.

First, the operator selects the backward performance measurement menu, the noise generator mode, the Eb / No value range and the number of Markov test calls through the terminal 100. Then, the terminal 100 outputs the backward performance measurement menu signal selected by the operator to the main processor 200. Subsequently, the main processor 200 determines whether the backward performance measurement menu selected by the operator is a reverse traffic performance test under additional noise (S1 ′).

In this case, if the backward performance measurement menu selected by the operator is a reverse traffic performance test under additional noise (YES), the main processor 200 may determine a noise generator mode, an Eb / No value range input by the operator through the terminal 100, and The number of Markov test calls is input (S2 ').

Meanwhile, the main processor 200 calculates a test execution count value using the Eb / No value range and the Markov test call count input through the terminal 100 and initializes test coefficients (S3 ′).

Thereafter, the main processor 200 performs a system initialization operation for performing a reverse traffic performance test under additional noise (S4 ′).

In this case, the system initialization operation (S4 ') for the reverse traffic performance test under the additional noise described above will be described in detail with reference to FIG. First, the main processor 200 initializes the Eb / No value range loop and the Markov test call count loop (S4'-1). In addition, the main processor 200 turns off the transmission power control function of the terminal 10 (S4'-2).

In addition, the RS-422 processor 510 mounted in the base station RS-422 controller 500 outputs a Markov test call transmission request signal to the base station 40 via the RS-422 interface 520. Then, the base station 40 requests the Markov test call transmission to the terminal 10 (S5 ').

Meanwhile, the main processor S200 determines whether the noise generator mode input by the operator is an Eb / No mode or a noise generator mode (S6 ').

In addition, if the noise generator mode input by the operator in the sixth step (S6 ') is Eb / No mode, the main processor 200 performs a Markov test call environment setting operation corresponding to the Eb / No mode ( S7 ').

At this time, the environment setting operation (S7 ') of the Markov test call corresponding to the Eb / No mode described above will be described in detail with reference to FIG. First, the noise generator 22 of the measurement equipment unit 20 receives a control signal output from the measurement equipment processor 810 and measures a transmission power value of the terminal 10 (S7'-1). ). Subsequently, the noise generator 22 calculates additional noise of the Markov test call based on the transmission power value measured by the noise generator and the Eb / No value input by the operator (S7'-2). In addition, the noise generator 22 sets additional noise to the Markov test call transmitted from the terminal 10 (S7'-3). On the other hand, the signal attenuator 21 attenuates the level of the Markov test call transmitted from the terminal 10 by an amount calculated to match the reception level of the base station 40 (S7'-4). Therefore, the Markov test call transmitted from the terminal 10 is changed to the same environment as the call processing signal of the actual situation.

Then, the terminal 10 transmits a plurality of Markov test calls whose environment is determined to the base station 40 (S8 '). Thus, the test preparation process for the reverse traffic performance test under additional noise through the above operation process is completed.

On the other hand, the RS-422 processor 510 mounted in the base station RS-422 control unit 500 performs a reverse traffic performance test under additional noise between the terminal 10 and the base station 40, and then returns the result. The log file 300 is stored (S9 ').

At this time, the reverse traffic performance test operation (S9 ') under the additional noise performed by the RS-422 processor 500 will be described in detail with reference to FIG. First, the base station 40 receives a plurality of Markov frames output from the terminal 10, and outputs the error rate to the RS-422 processor 510 (S9'-1). On the other hand, the RS-422 processor 510 receives a plurality of Markov frame error rates that have passed through the RS-422 interface 520 and stores them in the log file 300 (S9'-2). Subsequently, the RS-422 processor 510 outputs a Markov test call transmission blocking control signal to the base station 40, and the base station 40 outputs a Markov test call output from the RS-422 processor 510. After receiving the transmission blocking control signal, the Markov test call transmission operation of the terminal 10 is blocked (S9'-3). Meanwhile, the analysis module 600 reads frame error rates for a plurality of Markov test calls stored in the log file 300 and analyzes them, and analyzes the reverse traffic performance test result value under additional noise to the main processor 200. Output (S9'-4).

In addition, the main processor 200 compares the test execution count value calculated in the third step S3 ′ with the test coefficients to determine whether the main processor 200 is the same (S10 ′).

In this case, when the test execution count value and the test coefficient are not equal to each other (NO) in the tenth step (S10 '), the main processor 200 increases the test coefficient by “1” and then performs the fifth' step ( Proceed to S5 ') and perform reverse traffic performance test again under additional noise. However, if the test execution count value and the test coefficient are the same (YES) in the tenth step (S10 '), the main processor 200 displays a display control signal for displaying the reverse traffic performance test result to the operator under additional noise. Is output to the terminal 100. Then, the terminal 100 receives the display control signal output from the main processor 200 and displays the fading error rate for the plurality of Markov test calls, which are the results of the reverse traffic performance test under the additive noise (S11 '). ).

Therefore, the operator determines the reverse traffic performance under the additive noise between the terminal 10 and the base station 40 while looking at the fading error rate for the plurality of Markov test calls displayed through the terminal 100.

Meanwhile, in the sixth step S6 ', if the noise generator mode input by the operator is the noise generator mode, the main processor 200 performs the Markov test call environment setting operation corresponding to the noise generator mode, and then the The process proceeds to the eighth step S8 '(S12').

At this time, the environment setting operation (S12 ') of the Markov test call corresponding to the noise generator mode described above will be described in detail with reference to FIG. First, the spectrum analyzer 24 of the measurement equipment unit 20 receives a control signal output from the measurement equipment processor 810 and measures a transmission power value of the terminal 10 (S12'-1). ). Subsequently, the noise generator 22 calculates the additional noise of the Markov test call based on the transmission power value measured by the spectrum analyzer 24 and the Eb / No value input by the operator (S12'-2). In addition, the noise generator 22 sets additional noise to the Markov test call transmitted from the terminal 10 (S12'-3). On the other hand, the signal attenuator 21 attenuates the level of the Markov test call transmitted from the terminal 10 by an amount calculated to match the reception level of the base station 40 (S12'-4). Therefore, the Markov test call transmitted from the terminal 10 is changed to the same environment as the call processing signal of the actual situation.

Meanwhile, referring to FIG. 12, FIG. 13, FIG. 14, FIG. 15 and FIG. 16, a method for testing reverse traffic performance under multipath fading in a method for automatically measuring backward performance between terminals / base stations in a CDMA system according to an embodiment of the present invention. This will be described.

First, the operator selects the direction performance measurement menu, the noise generator mode, the Eb / No value range and the number of Markov test calls through the terminal 100. Then, the terminal 100 outputs the backward performance measurement menu signal selected by the operator to the main processor 200. Subsequently, the main processor 200 determines whether the backward performance measurement menu selected by the operator is a reverse traffic performance test under multipath fading (S1 ″).

At this time, if the backward performance measurement menu selected by the operator is a reverse traffic performance test under multipath fading (YES), the main processor 200 may enter a noise generator mode and an Eb / No value range input by the operator through the terminal 100. And receives the number of Markov test call (S2 ").

Meanwhile, the main processor 200 calculates a test execution count value using the Eb / No value range and the Markov test call count input through the terminal 100 and initializes test coefficients (S3 ″).

Thereafter, the main processor 200 performs a system initialization operation for performing reverse traffic performance test under multipath fading (S4 ″).

In this case, the system initialization operation (S4 ″) for the reverse traffic performance test under the multipath fading described above will be described in detail with reference to FIG. 13. First, the main processor 200 has an Eb / No value range. Loop and Markov test call count loops are initialized (S4 "-1). In addition, the main processor 200 turns off the transmission power control function of the terminal 10 (S4 ″ -2).

The main processor 200 outputs a multipath fading setting control signal to the measurement equipment processor 810, and the measurement equipment processor 810 sets the multipath fading output from the main processor 200. The control signal is input, and the multipath fading set value for determining the multifading pass characteristic of the Markov test call is transmitted to the fading emulator 23 (S5 ″).

In addition, the RS-422 processor 510 mounted in the base station RS-422 controller 500 outputs a Markov test call transmission request signal to the base station 40 via the RS-422 interface 520. Then, the base station 40 requests the Markov test call transmission to the terminal 10 (S6 ").

Meanwhile, the main processor S200 determines whether the noise generator mode input by the operator is an Eb / No mode or a noise generator mode (S7 ″).

At this time, if the noise generator mode input by the operator in the seventh step (S7 ") is the Eb / No mode, the main processor 200 performs the Markov test call environment setting operation corresponding to the Eb / No mode ( S8 ").

At this time, the environment setting operation (S8 ") of the Markov test call corresponding to the Eb / No mode described above will be described in detail with reference to Fig. 14. First, the noise generator 22 of the measuring equipment unit 20 is described. ) Receives the control signal output from the measurement equipment processor 810 and measures the transmission power value of the terminal 10 (S8 ″ -1). Subsequently, the noise generator 22 calculates the additional noise of the Markov test call based on the transmission power value measured by the user and the Eb / No value input by the operator (S8 ″ -2). In addition, the noise generator 22 Sets the additional noise to the Markov test call transmitted from the terminal 10 (S8 "-3). On the other hand, the signal attenuator 21 attenuates the level of the Markov test call transmitted from the terminal 10 by an amount calculated to match the reception level of the base station 40 (S8 " -4). The Markov test call transmitted in (10) is changed to the same environment as the call processing signal in the actual situation.

Then, the fading emulator 23 sets the multi fading pass characteristics in the Markov test call through the input multipath fading set values (S9 ").

Subsequently, the terminal 10 transmits a plurality of Markov test calls whose environment is determined to the base station 40 (S10 "). Thus, the test preparation for reverse traffic performance test under multipath fading through the above operation process. The process is complete.

Meanwhile, the RS-422 processor 510 mounted in the base station RS-422 control unit 500 performs a reverse traffic performance test under multipath fading between the terminal 10 and the base station 40, and then the result value. To the log file 300 (S11 ").

In this case, the terminal access probe acquisition test operation S11 ″ performed by the RS-422 processor 510 will be described in detail with reference to FIG. 15. A plurality of Markov frames output in step 10) are input and the error rates are output to the RS-422 processor 510 (S11 "-1). On the other hand, the RS-422 processor 510 receives a plurality of Markov frame error rates that have passed through the RS-422 interface 520 and stores them in the log file 300 (S11 "-2). The RS-422 process unit 510 outputs a Markov test call transmission block control signal to the base station 40, and the base station 40 outputs the Markov test call transmission block output from the RS-422 process unit 510. After receiving the control signal, the Markov test call transmission operation of the terminal 10 is blocked (S11 "-3). Meanwhile, the analysis module 600 reads frame error rates for a plurality of Markov test calls stored in the log file 300, and analyzes them, and analyzes the reverse traffic performance test result values under multipath fading. (S11 "-4).

In addition, the main processor 200 compares the test execution count value calculated in the third " step S3 " with the test coefficients to determine whether they are the same (S12 ").

In this case, when the test execution count value and the test coefficient are not equal to each other (NO) in the twelfth step S12, the main processor 200 increases the test coefficient by one and then increases the fifth test step. S5 ") to perform the reverse traffic performance test again under multipath fading. However, if the test execution count value and the test coefficient are the same (YES) in the twelfth step S12 ″, the main processor 200 controls display to display the reverse traffic performance test result to the operator under multipath fading. A signal is output to the terminal 100. Then, the terminal 100 receives the display control signal output from the main processor 200, and displays the fading error rate for the plurality of Markov test calls which are the results of the reverse traffic performance test under multipath fading (S13). ").

Therefore, the operator determines the reverse traffic performance under the multipath fading between the terminal 10 and the base station 40 while looking at the fading error rate for the plurality of Markov test calls displayed through the terminal 100.

On the other hand, in the seventh step (S7 "), if the noise generator mode input by the operator is the noise generator mode, the main processor 200 performs the Markov test call environment setting operation corresponding to the noise generator mode and then the The process goes to the ninth step S9 "(S14").

At this time, the environment setting operation (S14 ") of the Markov test arc corresponding to the noise generator mode described above will be described in detail with reference to Fig. 16. First, the spectrum analyzer 24 of the measurement equipment unit 20 is as follows. Receives a control signal output from the measurement equipment processor 810, and measures the transmission power value of the terminal 10 (S14 "-1). Subsequently, the noise generator 22 calculates additional noise of the Markov test call based on the transmission power value measured by the spectrum analyzer 24 and the Eb / No value input by the operator (S14 ″ -2). The noise generator 22 sets additional noise to the Markov test call transmitted from the terminal 10 (S14 "-3). On the other hand, the signal attenuator 21 attenuates the level of the Markov test call transmitted from the terminal 10 by an amount calculated to match the reception level of the base station 40 (S14 "-4). The Markov test call transmitted in (10) is changed to the same environment as the call processing signal in the actual situation.

As described above, according to the apparatus and method for automatic measurement of reverse performance between terminals and base stations in the CDMA system according to the present invention, since the reverse performance from the terminal to the base station is automatically measured, the measurement result is displayed to the operator. The backward performance measurement time is shortened and the operator is not only convenient to perform the measurement, but also the high performance computer analyzes the result of the reverse performance and displays it to the operator so that the operator can accurately determine the reverse performance between the terminal and the base station. Being able to do it has an excellent effect.

Claims (23)

A terminal for transmitting a predetermined number of access messages and a Markov test call during backward performance measurement; It consists of a signal attenuator, noise generator, fading emulator, and spectrum analyzer to control fading, additional noise, and signal attenuation on the Markov test call so that the Markov test call transmitted from the terminal is transmitted in the same situation as the call during actual call processing. Measuring equipment; A signal distributor; In the apparatus for measuring the backward performance from the terminal to the base station in a CDMA system consisting of a base station transmitting and receiving a Markov test call and an access message transmitted from the terminal, A terminal for outputting the selected data when the operator selects a backward performance measurement menu, a noise generator mode, an Eb / No value range, and a Markov test call number, and displays a reverse performance measurement result to the operator; After receiving the backward performance measurement menu signal, the noise generator mode signal, the Eb / No value range signal, and the Markov test call number signal outputted from the terminal, totally control the reverse performance measurement operation corresponding to the reverse performance measurement menu selected by the operator. And then, the main processor for displaying the final result of the backward performance test to the operator; A log file for storing successive backward performance measurement results; The terminal access probe acquisition test control signal output from the main processor is input, and the base station is controlled to perform the terminal access probe acquisition test, and then the successful access probe output from the base station is received and the test result is recorded in the log file. A base station RS-232 control unit for storing in the base station; A base station RS-422 control unit which outputs a Markov test call call request signal to the base station, receives a plurality of Markov frame error rates output from the base station, and stores the test result values in the log file; An analysis module for reading and analyzing a backward performance test result value stored in the log file, and outputting a final result of a backward performance test to the main processor; A terminal controller which receives a control signal output from the main processor and transmits a terminal configuration parameter to the terminal and controls an access message transmission operation of the terminal; And a measurement equipment controller configured to control the test call environment setting operation of the measurement equipment by receiving the control signal output from the main processor. The method of claim 1, The base station RS-232 control unit receives a terminal access probe acquisition test control signal from the main processor, outputs a terminal access probe acquisition test request signal to the base station, and then receives a plurality of successful access probes output from the base station. RS-232 processor for storing in the log file; And an RS-232 interface unit configured to perform a data interface operation between the base station and the RS-232 processor unit. The method of claim 1, The base station RS-422 control unit includes: an RS-422 processor for outputting a Markov test call call request signal to the base station, receiving a plurality of Markov frame error rates output from the base station, and storing them in the log file; And an RS-422 interface unit configured to perform a data interface operation between the base station and the RS-422 processor. The method of claim 1, The terminal controller receives a control signal output from the main processor, transmits a terminal configuration parameter to the terminal, outputs an access message transmission control signal for controlling an access message transmission operation, and transmits power of the terminal. A terminal processor for outputting a power control signal for controlling the control; And a terminal interface unit configured to perform a data interface operation between the terminal and the terminal processor. The method of claim 1, The measuring equipment control unit may include: a measuring equipment processor configured to receive a control signal output from the main processor and output a power measurement signal, a fading control signal, an additional noise control signal, and a signal attenuation control signal to the measurement equipment unit; And a measurement equipment interface configured to perform a data interface operation between the measurement equipment and the measurement equipment processor. The terminal access probe acquisition test method of the automatic measurement of the reverse performance between terminals and base stations in the CDMA system, A first step of determining whether the reverse performance measurement menu selected by the operator is a terminal access probe acquisition test; A second step of receiving, by the main processor, a noise generator mode, an Eb / No value range, and a Markov test call number input by an operator if the backward performance measurement menu selected by the operator in the first step is a terminal access probe acquisition test; A third step of the main processor calculating a test execution count value using an Eb / No value range and a Markov test call count and initializing test coefficients; A fourth step of performing a system initialization operation for performing a terminal access probe acquisition test; A fifth step of requesting transmission of a Markov test call from the base station RS-422 control unit to the terminal; A sixth step of determining, by the main processor, a noise generator mode input by an operator; A seventh step in which the main processor performs a Markov test call configuration setting operation corresponding to the Eb / No mode if the noise generator mode input by the operator in the sixth step is an Eb / No mode; An eighth step of the terminal transmitting a Markov test call whose environment is determined to the base station; A ninth step in which the base station RS-422 controller blocks transmission of a Markov test call; A tenth step of performing, by the base station RS-232 controller, a terminal access probe acquisition test between the terminal and the base station, and storing the result in the log file; An eleventh step, wherein the main processor compares a test execution count value with a test coefficient to determine whether the main processor is the same; If the test execution frequency value and the test coefficient are not the same in the eleventh step, the test coefficient is increased to " 1 ", and then the process proceeds to the fifth step. 12. A method for automatic measurement of reverse performance between terminals and base stations in a CDMA system, comprising a twelfth step of displaying acquisition test results to an operator. The method of claim 6, The fourth step includes: a fourth step of the main processor initializing an Eb / No value range loop and a Markov test call number loop; Step 4-2 in which the base station RS-422 controller sets a reverse measurement parameter of the base station; Step 4-3 of the terminal controller setting the reverse measurement parameter of the terminal; 4. The method of claim 4, wherein the terminal controller turns off the transmission power control function of the terminal. 4. The method of claim 6, The seventh step may include a seventh step of measuring a transmission power value of a terminal by a noise generator of the measuring equipment unit; A step 7-2 in which the noise generator calculates the amount of additional noise and signal attenuation of the Markov test call based on the transmission power value measured by the noise generator and the Eb / No value input by the operator; A step 7-3 in which the noise generator sets additional noise in a Markov test call transmitted from the terminal; And a seventh to fourth step in which the signal attenuator attenuates the level of the Markov test call transmitted from the terminal by an amount calculated by the measuring apparatus processor to match the base station reception level. Automatic measurement of reverse performance between The method of claim 6, In the sixth step, if the noise generator mode input by the operator is the noise generator mode, the main processor performs the Markov test call environment setting operation corresponding to the noise generator mode, and then proceeds to the eighth step S8. A method for automatically measuring reverse performance between terminals and base stations in a CDMA system, comprising the thirteenth step. The method of claim 9, The thirteenth step may include: a thirteenth step of the spectrum analyzer measuring the transmission power value of the terminal; Step 13-2, wherein the noise generator calculates additional noise of a Markov test call based on a transmission power value measured by the spectrum analyzer and an Eb / No value input by an operator; Step 13-3, wherein the noise generator sets additional noise to a Markov test call transmitted from the terminal; And a thirteenth to fourth step of attenuating the level of the Markov test call transmitted from the terminal by the signal attenuator. The method of claim 6, The tenth step may include: a tenth step of the base station RS-232 controller outputting a terminal access probe acquisition test request signal to the base station; A step 10-2 of the terminal controller outputting an access message transmission control signal to the terminal; A step 10-3 of the terminal transmitting the set number of access messages to the base station; A step 10-4 of the base station receiving a plurality of successful access probes and outputting them to the base station RS-232 control unit; A step 10-5 in which the base station RS-232 control unit receives a plurality of successful access probes and stores them in the log file; A step 10-6 of the base station RS-232 control unit outputting a terminal access probe acquisition test stop request signal to the base station; The analyzing module reads the successful access probe stored in the log file, and analyzes the result. The terminal / base station of the CDMA system comprises steps 10-7 of outputting a terminal access probe acquisition test result to the main processor. Automatic measurement of reverse performance between In the method of automatic measurement of reverse performance between terminals and base stations in CDMA system, the reverse traffic performance test method under additional noise is A first step of determining whether the reverse performance measurement menu selected by the operator is a reverse traffic performance test under additional noise; If the backward performance measurement menu selected by the operator in the first step is a backward traffic performance test under additional noise, the main processor receives a noise generator mode, an Eb / No value range, and a Markov test call number input by the operator; Step; A third 'step of the main processor calculating a test execution count value using an Eb / No value range and a Markov test call count and initializing test coefficients; A fourth 'step of performing a system initialization operation to perform a reverse traffic performance test under additional noise; A fifth step of requesting transmission of a Markov test call from the base station RS-422 control unit to the terminal; A sixth step of determining, by the main processor, a noise generator mode input by an operator; A seventh step in which the main processor performs a Markov test call configuration setting operation corresponding to the Eb / No mode if the noise generator mode input by the operator in the sixth step is an Eb / No mode; An eighth step of transmitting, by the terminal, a plurality of Markov test calls whose environment is determined to the base station; A ninth step of performing, by the base station RS-422 control unit, a reverse traffic performance test under the additional noise between the terminal and the base station, and storing the result in the log file; A tenth step in which the main processor compares a test execution count value with a test coefficient to determine whether the main processor is the same; If the test execution count value and the test coefficient are not equal to each other in the tenth step, the test coefficient is increased to "1" and then proceeds to the fifth step. If the test execution count value and the test coefficient are the same, the main processor adds the same. A method of automatic measurement of reverse performance between terminals and base stations in a CDMA system, comprising an eleventh step of displaying a result of a reverse traffic performance test under noise to an operator. The method of claim 12, The fourth step includes: a fourth '-1 step in which the main processor initializes an Eb / No value range loop and a Markov test call number loop; 4. The method of claim 4, wherein the terminal controller turns off the transmission power control function of the terminal. 4. The method of claim 12, The seventh step may include a seventh '-1 step in which the noise generator of the measuring equipment unit measures a transmission power value of the terminal; A 7'-2 step in which the noise generator calculates additional noise of a Markov test call based on a transmission power value measured by the noise generator and an Eb / No value input by an operator; Step 7'-3 in which the noise generator sets additional noise in a Markov test call transmitted from the terminal; And a 7'-4 step in which the signal attenuator attenuates the level of the Markov test call transmitted from the terminal. The method of claim 12, In the sixth step, if the noise generator mode input by the operator is the noise generator mode, the main processor performs the Markov test call environment setting operation corresponding to the noise generator mode, and then moves to the eighth step (S8 '). A method for automatically measuring reverse performance between terminals and base stations in a CDMA system, characterized by a 12th step that is performed. The method of claim 15, The twelfth step includes the twelfth'-1 step of the spectrum analyzer measuring the transmission power value of the terminal; A 12'-2 step in which the noise generator calculates additional noise of a Markov test call based on a transmission power value measured by the spectrum analyzer and an Eb / No value input by an operator; A 12'-3 step of setting additional noise to a Markov test call transmitted from the terminal by the noise generator; 12. The method of claim 12, wherein the signal attenuator attenuates the level of the Markov test call transmitted from the terminal. The method of claim 12, The ninth step includes: a ninth step '-1, in which the base station receives a plurality of Markov frames and outputs an error rate to the base station RS-422 control unit; A 9'-2 step in which the base station RS-422 control unit receives a plurality of Markov frame error rates and stores them in the log file; A 9'-3 step in which the base station RS-422 control unit blocks transmission of a Markov test call to a base station; The analysis module reads the frame error rate data of the plurality of Markov test calls stored in the log file, and analyzes the result. A method for automatically measuring reverse performance between terminals and base stations in a CDMA system. In the method of automatic measurement of reverse performance between terminals and base stations in CDMA system, the reverse traffic performance test method under multipath fading is A first " step of determining whether the reverse performance measurement menu selected by the operator is a reverse traffic performance test under multipath fading; and a reverse traffic performance test under multipath fading with the reverse performance measurement menu selected by the operator in the first " And a second " step of receiving, by the main processor, a noise generator mode, an Eb / No value range, and a Markov test call number input by an operator; the main processor tests using the Eb / No value range and the Markov test call number. A third "step of initializing the test coefficients while calculating the execution count value; Performing a system initialization operation for performing reverse traffic performance testing under multipath fading; and outputting, to the fading emulator, a multipath fading set value for determining the multifading pass characteristics of a Markov test call by the instrumentation control unit. A fifth "step; A sixth " step of requesting transmission of a Markov test call from the base station RS-422 control unit to the terminal; a seventh " step of the main processor determining a noise generator mode input by an operator; An eighth " step of performing, by the main processor, a Markov test call configuration setting operation corresponding to the Eb / No mode if the noise generator mode input by the operator in the seventh " step is Eb / No mode; A ninth step of setting a multi fading pass characteristic in a Markov test call through a multipath fading set value inputted by the fading emulator; and a tenth " for transmitting the plurality of Markov frames whose environment is determined to the base station by the terminal; Steps; An eleventh " step of performing, by the base station RS-422 controller, the reverse traffic performance test under the multipath fading between the terminal and the base station, and storing the result in the log file; A twelfth " step of comparing the test coefficients to determine whether they are the same; If the test execution count value and the test coefficient are not equal to each other in the twelfth step, the test coefficient is increased to "1", and then the process proceeds to the fifth "step. 13. A method for automatic measurement of reverse performance between terminals / base stations in a CDMA system, comprising the thirteenth step of displaying, to an operator, the results of a reverse traffic performance test under pass fading. The method of claim 18, The fourth " step includes: a fourth " -1 step in which the main processor initializes an Eb / No value range loop and a Markov test call number loop; And a fourth " -2 &quot; step of turning off the transmission power control function of the terminal by the terminal control unit. The method of claim 18, The eighth " step includes: an eighth " -1 step in which the noise generator of the measuring equipment unit measures a transmission power value of the terminal; Step 8 "-2, wherein the noise generator calculates an additional noise of a Markov test call based on a transmission power value measured by the noise generator and an Eb / No value input by an operator; a Markov test call transmitted by the noise generator from the terminal; An 8 " -3 step of setting additional noise to; And an 8 "-4 step of attenuating the level of the Markov test call transmitted from said terminal by said signal attenuator. The method of claim 18, In the seventh step, if the noise generator mode input by the operator is the noise generator mode, the main processor performs the Markov test call configuration setting operation corresponding to the noise generator mode, and then proceeds to the ninth step S9 ". A method for automatically measuring reverse performance between terminals and base stations in a CDMA system, comprising the step of proceeding to 14 ". The method of claim 21, The 14 " step includes: a 14 " " -1 step in which the spectrum analyzer of the measuring equipment unit measures a transmission power value of the terminal; Step 14 "-2, wherein the noise generator calculates an additional noise of a Markov test call based on a transmission power value measured by the spectrum analyzer and an Eb / No value input by an operator; a Markov signal transmitted from the terminal by the noise generator; A 14 " -3 step of setting additional noise in the test call; And the 14 &quot; -4 step of attenuating the level of the Markov test call transmitted from the terminal by the signal attenuator. The method of claim 18, The eleventh " step includes: an eleventh " -1 step in which the base station receives a plurality of Markov frames and outputs the error rate to the base station RS-422 control unit; An eleventh " -2 step of receiving, by the base station RS-422 control unit, a plurality of Markov frame error rates and storing them in the log file; and an eleventh " With three steps; The analysis module reads frame error rate data of a plurality of Markov test calls stored in the log file, analyzes the result, and outputs the reverse traffic performance test result under multipath fading to the main processor. A method for automatically measuring reverse performance between terminals and base stations in a CDMA system, characterized in that.