KR102485724B1 - Automatic measuring method for FM transmitter using GPIB - Google Patents

Abstract

The present invention relates to a method of automatically measuring an FM transmitter using GPIB. It is possible to significantly reduce testing time and also enhance the efficiency and convenience of a testing process. Since a test is performed based on the same setting values, the conventional problem of test results varying depending on a test tube can be significantly solved. Before performing a main test, the present invention is configured to perform a pre-processing test to determine whether an FM transmitter is modulating at a target modulation level. Thus, test accuracy and precision can be significantly enhanced. After calculating a pre-emphasis compensation value (R), an output value for each test item of the main test is compensated according to the calculated pre-emphasis compensation value (R), and then a result analysis is performed. Accordingly, it is possible to detect accurate test results by solving a current problem of mistakes and errors occurring depending on the characteristics of each FM transmitter.

Description

Automatic measuring method for FM transmitter using GPIB

The present invention relates to a method for automatically measuring an FM transmitter using GPIB, and more specifically, by connecting a measuring instrument and an examiner terminal with a USB/GPIB cable and installing a test-only program in the test-tube terminal under the control of the test-only program. As the FM transmitter of the instrument is configured to be tested, the test accuracy and precision can be increased, while the test convenience and efficiency can be improved. It relates to a method for automatically measuring an FM transmitter using GPIB, which can increase the efficiency of equipment operation.

An FM transmitter is composed of various electronic components and circuits, and when performance degradation of any one of these components and circuits occurs, the entire system, such as a terrestrial broadcasting station and a radio broadcasting station, is greatly affected.

Accordingly, domestic notices require regular tests of FM radio stations (an entity that emits or operates FM radio waves) such as terrestrial broadcasting stations and radio stations, and for such regular tests of FM transmitters, instruments are widely used. .

Conventionally, foreign-made measuring instruments are mainly used, but these foreign-made measuring instruments are not only very difficult to operate, but also have a problem in that the inspection time is very delayed because the software does not conform to domestic notices.

In particular, a terrestrial broadcasting station needs a quick test because it crosses the main transmitter and the auxiliary transmitter during the test, and has a disadvantage in that a number of errors occur in the test result for each measurer.

Korean Registered Patent No. 10-2014-0013464 relates to a method for testing the RF performance of a wireless communication device. Even if the transmission/reception timing of a test packet between a measuring instrument and a wireless communication device does not match due to a reset time delay, the Rx of the wireless communication device Disclosed is a technology capable of accurately measuring Rx performance of a wireless communication device by receiving all of the test packets required for performance testing.

The present invention is to solve this problem, and the problem of the present invention is to allow a test-only program to control the operation of the instrument through a USB/GPIB cable and to receive output values for each test item according to the FM modulation signal analysis from the instrument at the same time. By being configured, the test is automatically performed according to the preset test procedure, which can greatly reduce the test time, as well as increase the efficiency and convenience of the test process. It is to provide an automatic FM transmitter measurement method using GPIB that can dramatically solve the problem of changing.

In addition, another problem of the present invention is configured to perform a pre-processing test on whether the FM transmitter is modulated to a target modulation level before the test program performs the main test, thereby significantly increasing the test accuracy and precision. It is to provide a method for automatically measuring an FM transmitter using GPIB.

In addition, another problem of the present invention is to calculate the pre-emphasis compensation value (R) after the test-only program calculates the output value for each test item of the main test according to the calculated pre-emphasis compensation value (R). After compensation, it is configured to perform result analysis, so that each FM transmitter is configured to perform an automatic measurement method for FM transmitters using GPIB, which can detect accurate test results by solving the problem of minute errors and errors occurring according to the current characteristics of each FM transmitter. .

In addition, another problem of the present invention is to generate an inspection report by processing and analyzing the result data for each inspection item when the inspection-only program completes the test for each inspection item, and at the same time store the generated inspection report in a preset path. In order to provide an automatic measurement method for FM transmitters using GPIB, which can further increase the operation and management efficiency of FM transmitters in the future as the subject and examiner accurately recognize the current state of the FM transmitter through the test report provided. will be.

The solution of the present invention for solving the above problems includes an FM transmitter, which is a device under test, and an audio generator, obtains a signal output from the FM transmitter, and analyzes the FM modulation signal for the obtained output signal. In the FM transmitter automatic measurement method (S1) applied to the FM transmitter automatic measurement system including a tester terminal connected to the instrument and a data cable, and a test-only program for managing and controlling the operation of the instrument is installed. : The method of automatically measuring the FM transmitter (S1) includes a step 20 (S20) of an examiner connecting the FM transmitter and the examiner's terminal with a data cable; controlling the instrument to perform a pre-processing test to verify whether the test-only program is modulated to a target modulation level in the FM transmitter 40 (S40); Step 60 (S60), which proceeds when the verification of the preprocessing test is completed in step 40 (S40), wherein one of the test items preset in the test-only program is selected by a user; The step of the test-only program controlling the instrument so that the test of the test item is performed according to a preset test procedure corresponding to the test item selected in step 60 (S60), and receiving an output value for the selected test item from the instrument. 70 (S70); It proceeds after the step 70 (S70), and the dedicated test program determines whether all the tests for the preset test items have been performed. It includes a step 90 (S90) of proceeding to (S60), and the step 40 (S40) is performed after the measuring instrument generates a tone-signal of 1 kHz through the audio generator under the control of the test-only program, Step 401 of outputting to the FM transmitter (S401); Under the control of the inspection program, the instrument gradually increases the modulation level from 0 to 75%, which is the preset modulation level setting value (MV1), and then converts the modulation level setting value (MV1, 75%) to the FM modulator. Step 402 of outputting (S402); Step 403 (S403) of measuring the modulation level of the FM transmitter by demodulating and analyzing the output signal output from the FM modulator by the instrument; The inspection dedicated program compares whether the modulation level measurement value (MV2) detected in step 403 (S403) is included in the error range of 74.5 to 75.5% of the modulation level setting value (MV1, 75%), and if the modulation level If the level measurement value (MV2) is not included in the error range of 74.5 to 75.5% of the modulation level setting value (MV1, 75%), returning to the above step 402 (S402) and repeating the subsequent process step 404 (S404); In step 404 (S404), the modulation level measurement value (MV2) is carried out when the modulation level set value (MV1, 75%) is included in the error range of 74.5 to 75.5%, and the inspection exclusive program is verified at the 75% modulation level. At the same time as storing , a step 405 (S405) of calculating levels required for 50% modulation and 100% modulation using the verified 75% modulation level as a reference value using a preset equation.

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In addition, in the present invention, the step 405 (S405), when the level required for 50% modulation and 100% modulation is calculated by the inspection dedicated program, performs a preprocessing test for each modulation level, and then modulates any one of the modulation levels. If the level measurement value is out of the error range of the modulation level setting value, it is preferable to express a warning message through the test tube terminal.

In addition, in the present invention, the FM transmitter automatic measurement method (S1) is performed when it is determined that the tests of all test items are completed in step 90 (S90), and the test-only program processes and analyzes the test results for each test item. Thus, it is preferable to further include step 100 (S100) of generating an inspection report.

In addition, in the present invention, the method for automatically measuring the FM transmitter (S1) further includes step 50 (S50) performed after step 40 (S40), wherein step 50 (S50) is performed by the test dedicated program Using the data used in the preprocessing test for the 75% modulation level of S40), the modulation level measurement value (MV2) is subtracted from the modulation level setting value (MV1, 75%) to obtain the pre-emphasis compensation value (R). In step 60 (S60), when the test-only program receives the output value of the selected test item, the pre-emphasis compensation value (R) calculated in step 50 (S50) is applied to the received output value. It is desirable to analyze the test result using the value given.

According to the present invention having the above problems and solutions, the test-only program is configured to control the operation of the instrument through the USB/GPIB cable and to receive the output value for each test item according to the FM modulation signal analysis from the instrument at the same time, thereby establishing a predetermined test procedure. According to the test, the test is performed automatically, which can significantly reduce the test time, as well as increase the efficiency and convenience of the test process. can be solved

In addition, according to the present invention, the test-only program is configured to perform a pre-processing test to determine whether the FM transmitter is modulating as much as a target modulation level before performing the main test, so that test accuracy and precision can be remarkably improved.

In addition, according to the present invention, after the test exclusive program calculates the pre-emphasis compensation value (R), and compensates the output value for each test item of the main test according to the calculated pre-emphasis compensation value (R), By being configured to perform result analysis, it is possible to detect accurate test results by solving the problem of minute errors and errors occurring according to the current characteristics of each FM transmitter.

In addition, according to the present invention, when the test for each test item is completed, the test-only program generates an test report by processing and analyzing the result data for each test item, and at the same time stores the generated test report in a preset path. As the tester and examiner accurately recognize the current status of the FM transmitter through the provided inspection report, the operational and management efficiency of the future FM transmitter can be further increased.

1 is a configuration diagram showing an FM transmitter automatic measurement system to which an FM transmitter automatic measurement method using GPIB, which is an embodiment of the present invention, is applied.
2 is a flowchart showing a method for automatically measuring an FM transmitter using GPIB, which is an embodiment of the present invention.
FIG. 3 is a flowchart showing the preprocessing test step of FIG. 2 .

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a configuration diagram showing an FM transmitter automatic measurement system to which an FM transmitter automatic measurement method using GPIB, which is an embodiment of the present invention, is applied.

The FM transmitter automatic measurement system 1 using the GPIB of FIG. 1 is a system to which the FM transmitter automatic measurement method S1 using the GPIB of FIG. 2, which is an embodiment of the present invention, is applied.

In addition, as shown in FIG. 1, the FM transmitter automatic measurement system 1 using GPIB includes an examiner terminal 3, a test-only program 5, a measuring instrument 7, an FM transmitter 9, and a USB/GPIB cable. (10) consists of

The USB/GPIB cable 10 is a communication cable through which data is input/output by supporting compatibility of normal USB and GPIB, and the test tube terminal 3 and the instrument 7 transmit and receive data through the USB/GPIB cable 10. will do At this time, GPIB (General Purpose Interface Bus) is a communication standard for connecting a computer and peripheral devices, and USB (Universal Serial Bus) is one of serial bus standards for connecting peripheral devices to information devices.

The FM transmitter 9 is the equipment to be tested, which is the test target of the measuring instrument 7 of the present invention.

Such an FM transmitter 9 is a device that loads an input audio signal (voice, data, etc.) on a carrier wave, modulates and amplifies it, and transmits the modulated/amplified signal to the outside through an antenna.

At this time, since FM broadcasting modulates radio waves into frequencies, it has less noise and crosstalk and superior sound quality compared to conventional amplitude modulation (AM)-based broadcasting. In general, the frequency band of FM broadcasting in Korea is 88 to 108 MHz, and the bandwidth is 200 kHz.

In addition, when the FM transmitter 9 of the present invention receives a tone-signal from the measuring instrument 7, it modulates the input tone-signal and puts it on a carrier wave, amplifies it, and transmits the signal. At this time, the instrument 7 acquires (inputs) a signal output from the FM transmitter 9, demodulates and analyzes the obtained output signal to measure the modulation level of the FM transmitter 9, and measures the detected modulation level value ( MV2) is transmitted to the test-only program (5) through the USB/GPIB cable (10).

Since this FM transmitter 9 is a technology commonly and widely used in FM radio station systems, a detailed description thereof will be omitted, and various known technologies or technologies to be developed in the future may be applied.

The measuring instrument 7 is connected to the FM transmitter 9, which is a device under test, and is a testing device for testing the connected FM transmitter 9.

In addition, although the instrument 7 is not shown in the drawing, it is possible to transmit and receive data through an audio generator (not shown) that generates a tone-signal (stereo signal) and a USB/GPIB cable 10. A module (not shown) is included, and a GPIB type connector (not shown) for communication with the USB/GPIB cable 10 is installed on the outer surface of the housing of the instrument 9.

This measuring instrument 7 performs 1) a pre-processing test and 2) a main test under the control of the test-only program 5.

At this time, the pre-processing test is executed before the main test is performed, and it is verified whether the modulation is accurately performed in the FM transmitter 9 according to the modulation level set value (MV1) set in the FM transmitter 9, and at the same time, the main test is performed. It means a test to ensure that signal settings for the 50% modulation level and 100% modulation level, which are mainly used, are accurately and quickly performed, and the main test is a test to inspect the FM transmitter (9) for each inspection item according to domestic notification means

In addition, the audio generator of the measuring instrument (7) generates a tone-signal of 1 kHz under the control of the test program (5) during the pre-processing test and outputs it to the FM transmitter (9) while simultaneously modulating- The level is gradually increased until it reaches the preset modulation level setting value (MV1, 75%).

At this time, the FM transmitter 9 FM modulates the tone-signal input from the meter 7, puts it on a carrier wave, amplifies it, and outputs the signal.

In addition, the meter 7 acquires (inputs) the output signal transmitted from the FM transmitter 9, demodulates and analyzes the obtained output signal (RF signal), and measures the modulation level of the FM transmitter 9 (MV2). , The detected modulation level measurement value (MV2) is transmitted to the inspection dedicated program (5) through the USB/GPIB cable (10).

At this time, the inspection dedicated program 5 compares the modulation level set value (MV1, 75%) set in the measuring instrument 7 and the modulation level measurement value (MV2) transmitted from the measuring instrument 7, and determines whether the two values are the same. do.

In addition, the measuring instrument 7 transmits the measured value of each detected test item to the examiner terminal 3 through the USB/GPIB cable 10.

This measuring instrument 7 is configured to perform a test for each test item according to the domestic test notification, and in detail, the operation of the FM transmitter 9 is tested for each test item under the control of the test program 5.

The examiner's terminal 3 is a digital device possessed by the examiner, and in detail, may be composed of a laptop computer, a desktop PC, a smart phone, a tablet PC, a PMP, and the like.

In addition, the test tube terminal 3 transmits and receives data through the instrument 9 and the USB/GPIB cable 10, including a communication module and a connector, the same as the instrument 9.

In addition, a test-only program 5 is installed in the test tube terminal 3 .

The test-only program 5 is an application, software, or application program that manages and controls the operation of the instrument 9 so that the FM transmitter 9 is inspected in the instrument 9 according to the test procedure for each test item. It is an application.

That is, the measuring instrument 9 performs a test of the FM transmitter 9 for each preset test item under the control of the test program 5 .

At this time, the test of the inspection-only program 5 consists of 1) a pre-processing test and 2) a main test.

The preprocessing test means a test for checking whether the modulation of the instrument 7 is accurately performed before the main test is performed, and this preprocessing test will be described in detail in FIGS. 2 and 3 to be described later.

The main test refers to a test for checking the operation of the FM transmitter 9 for each predetermined inspection item according to domestic notices.

At this time, the inspection items are in accordance with the domestic test notice, and in detail, 'airline power', 'frequency tolerance', 'occupying frequency', 'spurious emission strength tolerance', 'signal-to-noise ratio', 'total distortion', 'total distortion' Frequency characteristics', 'Left-right signal level difference', 'Left-right separation', 'Transformation organization', 'Frequency shift of main carrier by pilot signal', 'Frequency of pilot signal', 'Phase error between pilot signal and subcarrier' ', 'shift of the main carrier plate due to the remaining subcarrier', 'residual amplitude modulation noise', and the like.

In addition, during the pre-processing test, the test program 5 first controls the instrument 7 to generate a 1kHz tone-signal from the audio generator of the instrument 7, and then gradually increases the modulation level from 0. After setting the modulation level to a preset modulation level setting value (MV1, 75%), the generated tone-signal is output to the FM transmitter 9.

At this time, the FM transmitter 9 modulates the tone-signal input from the meter 7 according to the modulation level set value (MV1, 75%), puts it on the carrier wave, amplifies it, and outputs the signal.

In addition, if the modulation level measurement value (MV2) is included in the error range of 74.5 to 75.5% of the modulation level setting value (MV1, 75%), the inspection dedicated program 5 sets the modulation level setting value (MV1, 75%). Using a known equation as a reference value, levels required for 50% modulation and 100% modulation widely used in the main test are calculated, and the preprocessing test is ended.

In addition, the test-only program 5 utilizes the data of the pre-processing test to calculate the pre-emphasis compensation value.

In general, when the FM transmitter 9 assumes that internal parts such as chips and circuits are ideal, modulation is performed according to the input modulation level setting value MV1 and pre-emphasis follows an ideal pre-emphasis curve. Since the sheath is made, the modulation level setting value (MV1) and the modulation level measurement value (MV2) have the same value, but each FM transmitter 9 has a set value (MV1) according to the state and characteristics of the internal parts It is not uncommon for MV2 to be applied differently from the actual modulation (MV2), and such an error acts as a factor that lowers the precision and accuracy of the main test described later, that is, the inspection for each inspection item.

That is, in order to solve this problem, the test-only program 5 of the present invention calculates the pre-emphasis compensation value R before performing the main test.

In other words, if the modulation level setting value (MV1, 75%) and the modulation level measurement value (MV2) are different from the inspection dedicated program 5, according to the current characteristics of the FM transmitter 9, the ideal pre-emphasis is If it is determined that this is not done, the pre-emphasis compensation value R is calculated by subtracting the modulation level measurement value MV2 from the modulation level setting value MV1.

For example, when the modulation level setting value (MV1) is 75% (-2.498dB) and the modulation level measurement value (MV2) is 74.5% (-2.556dB), the pre-emphasis compensation value (R) is 75 It is calculated as 0.5% ((-2.498dB) - (-2.556dB)) by subtracting 74.5% from %.

In addition, when the pre-emphasis compensation value is calculated, the test-only program 5 applies the pre-emphasis compensation value to the output value of each test item during the main test, and analyzes it to determine the characteristics of the FM transmitter 9. It is possible to increase the accuracy and precision of the inspection by compensating for the error according to the result.

For example, when the test-only program 5 performs the main test for the inspection item 'A', the output value Pn for the modulation level (X%) of the frequency band used for the inspection item 'A' - After calculating the value to which the emphasis compensation value is applied as the output value (X% (dB) + R (dB)), the test result for the test item is analyzed based on this.

In addition, when the calculation of the pre-emphasis compensation value (R) is completed, the test-only program 5 controls the measuring instrument 7 so that a test for each preset test item is performed by performing a main test.

At this time, the operation process of the pre-processing test, the calculation of the pre-emphasis compensation value, and the main test of the test-only program 5 will be described in detail with reference to FIGS. 2 and 3 to be described later.

In addition, when the main test is completed, the test-only program 5 processes and analyzes test results for each test item to generate an test report, and transmits the generated test report to preset test tube terminals and test subject terminals.

In this case, the inspection report may include inspection result information for each inspection item and corresponding information according to the inspection result.

That is, the examiner and the test subject can accurately and conveniently perform the test of the measuring instrument (7) through the test-only program (5), and can also perform the FM transmitter (9) by referring to the test report transmitted from the test-only program (5). By accurately recognizing the current state of the equipment, the efficiency of equipment operation can be maximized.

2 is a flowchart showing a method for automatically measuring an FM transmitter using GPIB, which is an embodiment of the present invention.

An embodiment of the present invention, a method for automatically measuring an FM transmitter using GPIB (S1), connects a measuring instrument and an examiner terminal with a USB/GPIB cable, and at the same time installs a test-only program in the test-tube terminal, and measures the instrument under the control of the test-only program As the FM transmitter is configured to be tested, the test accuracy and precision can be increased, and the convenience and efficiency of the test can be improved, and the examiner and the test subject can accurately recognize the equipment and operation status of the FM transmitter through the test report. This is to increase the efficiency of equipment operation.

In addition, as shown in FIG. 2, the FM transmitter automatic measurement method (S1) using the GPIB of the present invention includes a basic setting step (S10), a test tube terminal and instrument connection step (S20), and an FM transmitter and instrument connection step (S30). ), pre-processing test step (S40), pre-emphasis compensation value calculation step (S50), test item selection step (S60), selected item test step (S70), pre-emphasis correction step (S80), untested item It consists of a check step (S90) and an inspection report generation/storage step (S100).

In the basic setting step (S10), the examiner uses the dedicated test program (5) to determine the frequency of the FM transmitter (9), the audio output form of the audio generator of the instrument (7), and the screen screen-shot of the instrument (7). This step is to set the storage path (folder) of

The step of connecting the test tube terminal and the instrument (S20) is a step of connecting the test tube terminal 3 and the instrument 7 with the USB/GPIB cable 10.

At this time, the test tube terminal and instrument connection step (S20) is performed in a state in which all connections of the instrument 7 are disconnected to protect the FM transmitter 9. At this time, when the connection between the test tube terminal 3 and the measuring instrument 7 is completed, the test dedicated program 5 reads the basic information of the measuring instrument 7 through a command, displays it on the monitor, and restores the measuring instrument 7 to the basic state. After initialization, settings for the test of the FM transmitter 9 are automatically set.

The FM transmitter and instrument connection step (S30) is a step in which the examiner connects the FM transmitter 9 and the instrument 7 with a cable. At this time, through the step of connecting the FM transmitter and the instrument (S30), the instrument 7 outputs the tone-signal (1 kHz) of the preset modulation level generated by the audio generator to the FM transmitter 7 and to the FM transmitter 9 at the same time. The output FM signal can be input.

FIG. 3 is a flowchart showing the preprocessing test step of FIG. 2 .

The pre-processing test step (S40) of FIG. 3 is a step in which the test dedicated program 5 performs a test on whether modulation is performed according to the set modulation level when the FM transmitter 9 is level-modulated.

In addition, as shown in FIG. 3, the preprocessing test step (S40) includes a tone-signal generation step (S401), a modulation level increase/decrease step (S402), a modulation level analysis step (S403), and a modulation level verification step (S404). ), storing the modulation level and calculating 50% and 100% (S405).

In the tone-signal generation step (S401), the measuring instrument 7 generates a tone-signal of 1 kHz through an audio generator under the control of the test-only program 5, and then converts the generated tone-signal to FM. This is the step of outputting to the transmitter 9.

In the modulation level increase/decrease step (S402), the meter 7 adjusts the modulation level of the FM transmitter 9 from 0 to a preset modulation level setting value (MV1, 75%) under the control of the test dedicated program 5. It is a step that gradually increases/decreases until

That is, in the modulation level increasing/decreasing step (S402), the modulation level is increased until the instrument 7 reaches 75% (56.250 kHz), which is the set modulation level (MV1).

At this time, the meter 7 outputs the modulation level set value (MV1) to the FM transmitter 9 when the modulation level reaches the preset modulation level set value (MV1, 75%), and the FM transmitter 9 The tone-signal input from ) is FM-modulated according to the set modulation level setting value (MV1, 75%), loaded on the carrier wave, and then amplified to output the signal.

In the modulation level analysis step (S403), the instrument 7 demodulates and analyzes the output signal output from the FM transmitter 9 to measure the modulation level of the FM transmitter 9.

At this time, the FM transmitter 9 transmits the measured modulation level measurement value MV2 to the inspection dedicated program 5.

In the modulation level verification step (S404), the inspection dedicated program 5 determines that the modulation level measurement value (MV2) detected by the modulation level analysis step (S403) is within the error range (±0.5%) of the modulation level set value (MV1, 75%). It is a step of comparing whether or not it is included in %).

In addition, the modulation level verification step (S404) is 1) if the modulation level measurement value (MV2) is included in the error range (±0.5%) of the modulation level set value (MV1, 75%), the modulation level is stored as the next step and 50 The %, 100% calculation step (S405) is performed, and 2) if the modulation level measurement value (MV2) is out of the error range (±0.5%) of the modulation level setting value (MV1, 75%), modulation proceeds to the next step. The level increase/decrease step (S404) is performed so that the subsequent process is repeated.

The modulation level storage and 50%, 100% calculation step (S405) is performed when the verification is completed in the modulation level verification step (S404). At the same time, using a known equation, the levels required for 50% modulation and 100% modulation are calculated using the verified 75% modulation level as a reference value, and then stored.

In this way, the pre-processing test step (S40) of the present invention proceeds in advance before the main test, which is a test for each predetermined inspection item, is performed, and at the same time, according to the state and characteristics of the FM transmitter 9, the modulation of the FM transmitter 9 is set. It verifies whether the modulation is performed accurately according to the level, and at the same time calculates and stores the levels required for 50% modulation and 100% modulation widely used in the main test in advance, so that the modulation level applied to each inspection item is not individually verified. It can be used to significantly reduce test time.

Returning to FIG. 2 and looking at the pre-emphasis compensation value calculation step (S50), the pre-emphasis compensation value calculation step (S50) is performed when the pre-processing test is completed in the pre-processing test step (S40), and is a test-only program. (5) is a step of calculating the pre-emphasis compensation value R according to the current characteristics of the FM transmitter 9.

In addition, the pre-emphasis compensation value calculation step (S50) subtracts the modulation level measurement value (MV2) from the modulation level set value (MV1, 75%) used in the pre-processing test step (S40) to obtain a pre-emphasis compensation value. (R) is calculated.

For example, when the modulation level setting value (MV1) is 75% (-2.498dB) and the modulation level measurement value (MV2) is 74.5% (-2.556dB), pre-emphasis compensation value calculation step (S50) is calculated as 0.5% ((-2.498dB)-(-2.556dB)) by subtracting the modulation level measurement value (MV2, 74.5% (-2.556dB)) from the modulation level set value (MV1, 75% (-2.498dB)) do.

In the inspection item selection step (S60), the dedicated inspection program 5 receives a user's selection of one of preset inspection items.

At this time, the inspection items are 'aerial power', 'frequency tolerance', 'significant occupied frequency', 'spurious emission intensity tolerance', 'signal-to-noise ratio', 'total distortion', 'total frequency characteristics', 'left and right signal level difference' , 'left-right separation', 'transformation', 'frequency shift of main carrier by pilot signal', 'frequency of pilot signal', 'phase error between pilot signal and subcarrier', 'main carrier by residual of subcarrier' It can be composed of 'plate shift', 'residual amplitude modulation noise', and the like.

In the selection item inspection step (S70), the test-only program 5 controls the measuring instrument 7 according to a preset test procedure corresponding to the inspection item selected in the inspection item selection step (S60) to test according to the selected inspection item. It is a step that makes the

The pre-emphasis correction step (S80) is a step of performing pre-emphasis correction using the pre-emphasis circuit equipped with the FM transmitter 9 during the selection item checking step (S70).

In addition, in the selected item inspection step (S70), when the test for the selected inspection item is completed, the untested item check step (S90) is performed. At this time, the selection item inspection step (S70) uses the value to which the pre-emphasis compensation value (R) calculated in the pre-emphasis compensation value calculation step (S50) is applied when the output value of the selected inspection item is detected. do

The untested item checking step (S90) is a step in which the test-only program 5 checks whether all tests of preset inspection items have been completed.

In addition, in the untested item checking step (S90), 1) if it is determined that there is an inspection item for which the test has not yet been performed, a guide message is displayed to the user and whether or not to proceed as it is is selected from the user, 2) if a preset inspection When it is determined that the tests for all items are completed, the next step is to generate/store an inspection report (S100).

The test report creation/storage step (S100) is performed according to the completion of the test for all of the preset test items in the untested item check step (S90) or the user's choice of whether or not to proceed, and the test-only program (5) selects This is a step of processing and analyzing the test results for each inspection item performed in the item inspection step (S70) to generate an inspection report, and then storing the generated inspection report in the examiner terminal 3.

In addition, in the test report generation/storage step (S100), when the test report is generated, the test report is stored in a preset path of the test subject terminal or examiner terminal, so that the examiner or the test subject can refer to the test report, and the corresponding FM transmitter ( 9) It is possible to establish an overall plan for equipment inspection, replacement, condition, operation, etc.

In the FM transmitter automatic measurement method (S1) using GPIB, which is an embodiment of the present invention configured as described above, the test-only program controls the operation of the instrument through the USB/GPIB cable, and at the same time, the test item according to the analysis of the FM modulation signal from the instrument By being configured to receive each output value, the test is automatically performed according to the preset test procedure, which can significantly reduce the test time as well as increase the efficiency and convenience of the test process. It can dramatically solve the problem that test results vary depending on the test tube.

In addition, the FM transmitter automatic measurement method (S1) using the GPIB of the present invention is configured to perform a pre-processing test on whether the FM transmitter is modulating as much as the target modulation level before the test program performs the main test. Accuracy and precision can be significantly improved.

In addition, in the FM transmitter automatic measurement method (S1) using the GPIB of the present invention, after the test dedicated program calculates the pre-emphasis compensation value (R), according to the calculated pre-emphasis compensation value (R), the main test After compensating for the output value for each inspection item of , it is configured to perform result analysis, so that it is possible to detect accurate inspection results by solving the problem that minute errors and errors occur according to the current characteristics of each FM transmitter.

In addition, the FM transmitter automatic measurement method (S1) using the GPIB of the present invention generates an inspection report by processing and analyzing the result data for each inspection item when the inspection-only program completes the test for each inspection item, and simultaneously generates a test report. By being configured to store the report in a preset path, the test subject and examiner can accurately recognize the current state of the FM transmitter through the provided test report, thereby further increasing operational and management efficiency of the FM transmitter in the future.

1: FM transmitter automatic measurement system 3: Test tube terminal
5: Exclusive program for inspection 7: Measuring instrument
9:FM transmitter 10:USB/GPIB cable
S1: How to automatically measure an FM transmitter S10: Basic setting steps
S20: Test tube terminal and instrument connection step
S30: FM transmitter and instrument connection step
S40: Pre-processing test step S50: Pre-emphasis compensation value calculation step
S60: Inspection item selection step S70: Selected item inspection step
S80: Pre-emphasis correction step S90: Uninspected item check step
S100: Inspection report creation / storage step
S401: tone-signal generation step S402: modulation level increase/decrease step
S403: Modulation level analysis step S404: Modulation level verification step
S405: Storing the modulation level and calculating 50% and 100%

Claims (5)

An instrument under test, including an FM transmitter and an audio generator, which obtains a signal output from the FM transmitter and analyzes the FM modulated signal for the obtained output signal, and manages and controls the operation of the instrument In the FM transmitter automatic measurement method (S1) applied to an FM transmitter automatic measurement system including an examiner terminal connected to the instrument and a data cable and having a test-only program installed therein:
The FM transmitter automatic measurement method (S1)
Step 20 (S20) of an examiner connecting the FM transmitter and the examiner's terminal with a data cable;
controlling the instrument to perform a pre-processing test to verify whether the test-only program is modulated to a target modulation level in the FM transmitter 40 (S40);
Step 60 (S60), which proceeds when the verification of the preprocessing test is completed in step 40 (S40), wherein one of the test items preset in the test-only program is selected by a user;
The step of the test-only program controlling the instrument so that the test of the test item is performed according to a preset test procedure corresponding to the test item selected in step 60 (S60), and receiving an output value for the selected test item from the instrument. 70 (S70);
It proceeds after the step 70 (S70), and the dedicated test program determines whether all the tests for the preset test items have been performed. Including step 90 (S90) of proceeding to (S60),
The step 40 (S40) is
Step 401 (S401) of generating a tone-signal of 1 kHz by the instrument through the audio generator under the control of the test-only program and then outputting the tone-signal to the FM transmitter;
Under the control of the inspection program, the instrument gradually increases the modulation level from 0 to 75%, which is the preset modulation level setting value (MV1), and then converts the modulation level setting value (MV1, 75%) to the FM modulator. output step 402 (S402);
Step 403 (S403) of measuring the modulation level of the FM transmitter by demodulating and analyzing the output signal output from the FM modulator by the instrument;
The inspection dedicated program compares whether the modulation level measurement value (MV2) detected in step 403 (S403) is included in the error range of 74.5 to 75.5% of the modulation level setting value (MV1, 75%), and if the modulation level If the level measurement value (MV2) is not included in the error range of 74.5 to 75.5% of the modulation level setting value (MV1, 75%), returning to the above step 402 (S402) and repeating the subsequent process step 404 (S404);
In step 404 (S404), the modulation level measurement value (MV2) is performed when the modulation level set value (MV1, 75%) is included in the error range of 74.5 to 75.5%, and the inspection exclusive program is verified at the 75% modulation level. Step 405 (S405) of calculating levels required for 50% modulation and 100% modulation using the verified 75% modulation level as a reference value using a preset equation while storing Automatic measurement method (S1). delete The method of claim 1, wherein the step 405 (S405)
When the inspection dedicated program calculates the levels required for 50% modulation and 100% modulation, after performing a preprocessing test for each modulation level, the modulation level measurement value of any one of each modulation level is within the error range of the modulation level setting value. If it is out of , an FM transmitter automatic measurement method (S1), characterized in that a warning message is expressed through the test tube terminal. The method of claim 3, wherein the method for automatically measuring the FM transmitter (S1)
It proceeds when it is determined that the testing of all inspection items is completed in step 90 (S90), and further step 100 (S100) of generating an inspection report by processing and analyzing the inspection results for each inspection item by the inspection dedicated program. FM transmitter automatic measurement method (S1), characterized in that it comprises. The method of claim 3 or 4, wherein the method (S1) for automatically measuring the FM transmitter further comprises step 50 (S50) performed after step 40 (S40),
The step 50 (S50) is
The test dedicated program subtracts the modulation level measurement value (MV2) from the modulation level setting value (MV1, 75%) using the data used in the preprocessing test for the 75% modulation level in step 40 (S40) to free - Calculate the emphasis compensation value (R),
The step 60 (S60) is
When the test-only program receives the output value of the selected test item, the test result is analyzed by utilizing the value obtained by applying the pre-emphasis compensation value (R) calculated in step 50 (S50) to the received output value. FM transmitter automatic measurement method (S1), characterized in that for doing.

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