JP5069729B2 - Mobile communication terminal test system and calibration method thereof - Google Patents

Description

  The present invention has a pseudo base station function capable of communication connection with a mobile communication terminal, and tests the anti-jamming wave performance of the mobile communication terminal, or tests spurious contained in a transmission wave from the mobile communication terminal. The present invention relates to a mobile communication terminal test system. The present invention also relates to a calibration method for the mobile communication terminal test system.

  Among “Multiple Access” systems that allow multiple users to talk at the same time, the “Code Division Multiple Access (CDMA)” system, which is excellent in frequency utilization efficiency, can be put into practical use by multiple methods. It was. Among these plural systems, in particular, “Wideband-Code Division Multiple Access (W-CDMA)”, which is one system of the international standard IMT-2000 defined by the International Telecommunications Union (ITU), is called “Wideband / Code Division Multiple Access”. There is a “connection” method, and mobile communication terminals using this connection method have been put into practical use. Furthermore, a next-generation mobile communication standard called LTE (Long Term Evolution) is being formulated.

  Communication systems and data formats related to the above W-CDMA system and LTE system have been studied by 3GPP (3rd. Generation Partnership Project) and standardized as international standards, and mobile communication terminals and base station apparatuses comply with these standards. It is necessary to comply.

  Test content and measurement items for confirming compliance with this 3GPP standard are defined as conformance tests, and a test system for conducting conformance tests is provided. Includes a jamming test that verifies the anti-jamming wave performance (reception characteristics) of a mobile communication terminal and a transmission test that verifies spurious (one of the transmission characteristics) included in the transmission wave from the mobile communication terminal. It is.

  In the jamming wave test, a pseudo base station signal obtained by synthesizing the jamming wave is transmitted from a test system including a pseudo base station to a mobile communication terminal, and whether the mobile communication terminal correctly returns a response signal to the pseudo base station signal. Confirmation and verification confirms compliance with the standard. The interference signal generated by the signal generator is combined with the pseudo base station signal and transmitted to the mobile communication terminal for testing. At this time, in order to avoid the influence of the interference wave due to the carrier component, the component corresponding to the carrier frequency band is excluded from the interference wave signal generated by the signal generator, and the interference wave, the pseudo base station signal, Is synthesized.

  Also, in the transmission test, compliance with the standard is confirmed by measuring spurious included in the signal transmitted from the mobile communication terminal. When measuring spurious signals, signal components corresponding to the original response signal are not subject to measurement, so to prevent the original response signal from affecting the test, the original response signal is Spurious is measured after removing the component corresponding to the frequency band of the signal.

  As described above, in the interference wave test and the transmission test, a function called a band rejection filter that excludes a component of a specific frequency band is required, and in these tests, a frequency band used for mobile communication (for example, , 500 MHz to 3 GHz), it is necessary to verify each of the signals having various frequency bandwidths defined by the 3GPP standard. Hereinafter, a frequency band used for mobile communication is referred to as a communication frequency band.

  Patent Document 1 describes a radio base station test apparatus using a band rejection filter and a test method therefor. Similar to the band rejection filter of the test apparatus described in Patent Document 1, in the conventional mobile communication terminal test system, a plurality of fixed filters are switched and used as the band rejection filter. A conceptual diagram of such a mobile communication terminal test system is shown in FIG. FIG. 9 is a diagram schematically showing each path including a configuration for performing each test. Among them, path switching suitable for measurement items (jamming wave test and transmission test) using a band rejection unit is shown. It is a figure which shows an example. That is, in this mobile communication terminal test system, a signal generator 13 that generates a test signal or a calibration signal, a band rejection filter unit 10C that attenuates a signal in a desired frequency band in the test signal, and an interface unit 11 And a signal receiver 14 for receiving a test signal transmitted from the signal generator 13 or a signal from the mobile communication terminal 3, and a signal switch 14 side (terminal 16a) or a signal generator 13 side (terminal) by a changeover switch 16. A connector 15 connected to 16b) for inputting / outputting signals and a control unit 12 for controlling the operation of each functional block described above are provided.

  The connector 15 is connected to the mobile communication terminal 3 which is a terminal to be measured. In the case of the interference wave test, the connector 15 is connected to the signal receiver 14 side (terminal 16a), the mobile communication terminal 3 is connected to the connector 15, and the test signal transmitted by the signal generator 13 is transmitted to the mobile body. The signal is received by the communication terminal 3 and the anti-jamming wave characteristic of the mobile communication terminal 3 is tested. In the case of a transmission test, the connector 15 is connected to the signal generator 13 side (terminal 16b), the mobile communication terminal 3 is connected to the connector 15, and then a signal is transmitted from the mobile communication terminal 3 to the signal. The spurious contained in the signal is measured by receiving the signal at the receiver 14.

  The interface unit 11 is composed of a unit 11A and a unit 11B that indicate a network before and after the band rejection filter unit 10C. By switching control of the built-in changeover switch, the interface unit 11 can be selected from a plurality of routes (route A to route M). These routes can be selected. In each route from route A to route M, circuit members are built in different configurations for each route to form a circuit network, and necessary routes are selected and switched according to the test to be performed. The switching of the route is controlled by the control unit 12.

  The path R (R = A to M) in the unit 11A and the unit 11B schematically shows a combination of paths for the purpose of explaining the present invention, and is simply referred to as the path R (R = A to M). In the description, it is assumed that the subscript paths corresponding to both the unit 11A and the unit 11B are selected. At this time, the paths with the same subscripts in the units 11A and 11B do not indicate that they have the same configuration, and each of the units 11A and 11B does not necessarily have M paths. It is not necessary to have.

  In the band rejection filter unit 10C, a plurality of band rejection fixed filters (BRF-1 to BRF-N) are arranged in parallel, and one of the filters can be selected by switching control of the built-in changeover switch. It is configured. The center frequency and bandwidth of the signal attenuated by the band rejection filter unit 10 </ b> C are determined by a test to be performed, and switching of a filter to be used (set frequency band) is controlled by the control unit 12. The number of built-in band rejection type fixed filters depends on the number of communication frequency bands required for the test to be performed, and is set according to the standard of the test to be performed. An example of such a mobile communication terminal test system is disclosed in Patent Document 2.

  In recent years, technical specifications such as HSPA (High Speed Packet Access), which is an upper standard of W-CDMA, have been incorporated, LTE standards have been formulated, etc. The range of specifications has been added and changed, and frequencies that can be used accordingly Bands have been added and changed, and it is necessary to expand the range of frequency bands that can be verified even in a test system. That is, the frequency used for communication and its bandwidth vary depending on the communication standard and the frequency band allocation of the communication carrier. For this reason, the band rejection filter in the test system needs to correspond to the various frequencies and bandwidths.

JP 2006-128913 A JP 2003-18104 A

  In the test (interference wave test and transmission test), a signal having a desired output level needs to be input / output at the connector 15 to which the mobile communication terminal 3 which is a terminal to be measured is connected. However, the signal is attenuated due to differences in path loss, changes in temperature environment, aging, and the like. These effects vary depending on the route, and the test is performed by switching the route for each item. Therefore, it is necessary to calibrate the signal level for each route. In the following description, a device for testing the mobile communication terminal 3 that is a terminal to be measured, that is, the signal generator 13 in the interference wave test or the signal receiver 14 in the transmission test may be referred to as a tester.

  In the conventional method, as shown in FIG. 9, the band rejection filter unit 10C has a band (f1 to fN) corresponding to the setting of the frequency band for performing the test (hereinafter, this setting may be referred to as “frequency setting”). A blocking type fixed filter is used by switching. Therefore, it is necessary to calculate the calibration value for calibrating the output level of the signal transmitted by the signal generator 13 after calculating the loss amount between the paths for each filter for every path. . FIG. 10 is an example of a calibration table that stores the calculated calibration values.

FIG. 10 (a). Is a calibration table created in advance before the test (before adjustment or after adjustment after installing the test system at the user's site, or after adjustment of the test system configuration). Are calculated for all frequency settings (f1 to fN) to be tested for each route. This table shows calibration values α1 ′ _R fx (R = A to M; fx = f1 to fN; α1 ′ _A f1 to α1 ′ _M fN) for calibrating the path loss between the signal generator 13 and the connector 15. This is a frequency calibration table Tbl1 ′ to be stored, and calibrates a change in signal level due to a path loss for each path and a frequency characteristic for each frequency setting. FIG. 10 (b). Is a calibration table created immediately before the test is performed, and for the frequency setting (any one of f1 to fN) for performing the test for the path (any one of the path A to the path M) for performing the corresponding test, This is a frequency calibration table Tbl2 ′ for storing a calibration value β ′ _R fx for calibrating the path loss between the signal generator 13 and the signal receiver 14, and mainly changes in the signal level due to changes in temperature environment and aging. Calibrate.

In the interference wave test, in order to output a signal of a desired output level from the connector 15, the output level of the signal transmitted by the signal generator 13 is calibrated based on the calibration value α1 ′ _R fx and the calibration value β ′ _R fx. . In the transmission test, in order to measure the output level of the signal transmitted from the connector 15 by the signal receiver 14, the signal receiver is based on the calibration value α1 ′ _R fx and the calibration value β ′ _R fx. 14 corrects the output level of the received signal.

The calibration values (α1 ′ _R fx and β ′ _R fx) described above need to be calculated before performing the test and immediately before performing the test as calibration of the signal level of the tester related to the band rejection filter unit 10C. As shown in FIG. 10, the following processing cost is required to calculate the calibration value. Here, the processing cost is an index corresponding to the time taken to calculate the calibration value.

(Processing cost for obtaining calibration values before test (before shipment))
= (Calculation value α1 ′ _R fx calculation count)
= NxM

  Further, when the frequency setting to be measured is added due to the addition / change of the standard, the influence on the maintenance due to the calculation of the calibration value appears significantly. In the conventional method, it is necessary to add a band-stop type fixed filter for newly added frequency settings, and re-acquire a calibration value for the added fixed filter. FIG. 11 is a diagram for explaining a portion where a calibration value needs to be newly calculated by adding a frequency setting, and is illustrated as having frequencies fa1 to fan added.

  As shown in FIG. 11, when frequency settings for frequencies fa1 to fan are added, it is necessary to newly calculate a calibration value for the added frequency setting. The calculation of the calibration value requires the following processing costs. Necessary.

(Processing cost related to calibration value acquisition before test execution (during adjustment) due to frequency setting addition)
= (Calculation value α1 ′ _R fx calculation count)
= N × M

  In recent years, the frequency setting to be tested has increased, and this frequency setting has further increased due to the addition of regulations and the like, resulting in an increase in work time related to system maintenance.

  The present invention solves the above-described problem, and in a frequency band for mobile communication, a process for calculating a calibration value that accompanies an increase in frequency setting, flexibly corresponding to the frequency of the signal to be attenuated and the frequency band. By reducing costs (calibration value acquisition time) to a lesser extent, the increase in man-hours and work time at the time of system construction can be suppressed, and additions / changes of specifications, that is, changes in the range of available frequency bands can be flexibly handled. It is an object of the present invention to provide a mobile communication terminal test system using a band-stop filter unit that has been made possible and a calibration method for the mobile communication terminal test system.

In order to achieve the above object, the invention described in claim 1 includes a signal generator (13), a signal receiver (14), a connector (15) for connecting to a mobile communication terminal, and a desired A band rejection filter unit (10) for attenuating a signal in a frequency band, and the signal generator, the signal receiver, the connector, and the band rejection filter unit for performing a predetermined test of the mobile communication terminal. A switching interface unit (11) configured to perform the predetermined test by switching each path between the mobile communication terminal and the signal generator or the signal receiver as a tester. In the mobile communication terminal test system for performing the test, the band rejection filter unit is configured with a YTF and sets the tuning frequency of the YTF to a predetermined frequency. A variable band rejection filter (101) for attenuating a signal in a desired frequency band and a through path (102) for allowing the signal in the desired frequency band to pass without attenuation, the variable band rejection filter and the through path, Between the tester and the connector when the path is switched by the switching interface unit in a state where a through path is selected by the band rejection filter unit in advance. _A calibration data memory (123) for storing the path loss of each path as a first calibration value (α1 _A ,..., Α1 _M ), and at the beginning of the predetermined test, in the band rejection filter unit The test when the through path is selected and the path is configured to perform the predetermined test by the switching interface unit. Vessel and second calibration values path loss measured between the connector stores as ([alpha] 2 _R), the path is intact, the predetermined test the tuning frequency in the band rejection filter unit Calibration data acquisition for measuring a path loss between the tester and the connector when the variable band rejection filter set to a frequency corresponding to the frequency is selected and storing it as a third calibration value (β _R fx) When the control unit (122) and the predetermined test are tests of reception characteristics of the mobile communication terminal, the output level of the signal generator used as the tester is determined by the predetermined test. In the case of a test of transmission characteristics of the terminal, the reception level of the signal receiver used as the tester is calibrated by the first calibration value, the second calibration value, and the third calibration value. , Characterized by comprising a test control unit for performing the predetermined test (124).
The invention according to claim 2 is the mobile communication terminal test system according to claim 1, wherein the test control unit passes through the path and the band rejection filter unit from the signal generator. When a signal is input to the mobile communication terminal via the connector and the reception characteristic of the mobile communication terminal is tested, the first calibration value and the initial test at the start of the reception characteristic test are performed. The fluctuation amount of the first calibration value (= the second calibration value−the first calibration value) and the loss amount of the variable band rejection filter at the beginning of the start of the reception characteristic test (= the first calibration value) 3) —calibrating the level of the signal output from the signal generator based on the calibration value of 3−the second calibration value), supplying a signal of a desired level to the mobile communication terminal for testing It is characterized by that.
The invention according to claim 3 is the mobile communication terminal test system according to claim 1, wherein the test control unit sends a signal from the mobile communication terminal to the route and the connector via the connector. When testing the transmission characteristics of the mobile communication terminal received by the signal receiver via the connector via the band rejection filter unit, the first calibration value, the transmission characteristics test The fluctuation amount of the first calibration value in the initial stage at the start (= the second calibration value−the first calibration value), and the loss of the variable band rejection filter in the initial stage at the start of the transmission characteristic test Measure the level of the signal from the mobile communication terminal by calibrating the level of the signal received by the signal receiver based on the minute (= the third calibration value−the second calibration value) Special test To.
Further, the invention described in claim 4 attenuates a signal in a desired frequency band, a signal generator (13), a signal receiver (14), a connector (15) for connection to a mobile communication terminal, and the like. And a path between the signal generator, the connector, the signal receiver, and the band rejection filter unit for performing a predetermined test of the mobile communication terminal. And a switching interface unit (11) for performing the predetermined test by switching the mobile communication terminal using the signal generator or the signal receiver as a tester. A method for calibrating a body communication terminal test system, wherein the band rejection filter unit is composed of YTF and sets the tuning frequency of the YTF to a predetermined frequency. A variable band rejection filter (101) for attenuating a signal in a waveband and a through path (102) for allowing the signal in the desired frequency band to pass through without being attenuated, and one of the variable band rejection filter and the through path Further, each path between the tester and the connector when the path is switched by the switching interface unit in a state where the through-path is selected by the band rejection filter unit in advance. the path loss first calibration value _{(α1 a, ···, α1 M} ) a preparation step for storing as, if the predetermined trials are testing the reception characteristics of the mobile communication terminal, the received Initially at the start of a characteristic test, the band rejection filter unit selects the through path, and the switching interface unit A path loss between the tester and the connector when the path is configured to test the reception characteristic and the signal receiver is configured to be connected to the mobile communication terminal in parallel with the path to the connector After the pre-test path calibration value acquisition step of measuring and storing as a second calibration value (α2 _R ), and after the pre-test path calibration value acquisition step, the path is left as it is in the band rejection filter unit. A third calibration value (β _R) is measured by measuring a path loss between the tester and the connector when the variable band rejection filter having the tuning frequency set to a frequency corresponding to the predetermined test is selected. fx), a pre-test filter calibration value acquisition step, and a pre-test filter calibration value acquisition step, and an initial stage at the start of the test of the first calibration value and the reception characteristic. Variation of the first calibration value (= second calibration value−first calibration value) and loss of the variable band rejection filter at the beginning of the reception characteristic test (= the first calibration value) 3)-the second calibration value), the signal level output from the signal generator is calibrated to supply a signal of a desired level to the mobile communication terminal. And a calibration step for testing the characteristics.
Further, the invention according to claim 5 attenuates a signal in a desired frequency band, a signal generator (13), a signal receiver (14), a connector (15) for connecting to a mobile communication terminal, and the like. And a path between the signal generator, the connector, the signal receiver, and the band rejection filter unit for performing a predetermined test of the mobile communication terminal. And a switching interface unit (11) for performing the predetermined test by switching the mobile communication terminal using the signal generator or the signal receiver as a tester. A method for calibrating a body communication terminal test system, wherein the band rejection filter unit is composed of YTF and sets the tuning frequency of the YTF to a predetermined frequency. A variable band rejection filter (101) for attenuating a signal in a waveband and a through path (102) for allowing the signal in the desired frequency band to pass through without being attenuated, and one of the variable band rejection filter and the through path Further, each path between the tester and the connector when the path is switched by the switching interface unit in a state where the through-path is selected by the band rejection filter unit in advance. And a step of storing the path loss as the first calibration value (α1 _A ,..., Α1 _M ) and the transmission when the predetermined test is a test of transmission characteristics of the mobile communication terminal. Initially at the start of a characteristic test, the band rejection filter unit selects the through path, and the switching interface unit A pre-test path calibration value acquisition step for configuring a path to test the transmission characteristic and measuring a path loss between the tester and the connector and storing the path loss as a second calibration value (α2 _R ); After the pre-test path calibration value acquisition step, when the variable band-stop filter in which the tuning frequency is set to a frequency corresponding to the predetermined test is selected by the band-stop filter unit while the path remains unchanged After the pre-test filter calibration value acquisition step of measuring the path loss between the tester and the connector and storing it as a third calibration value (β _R fx), the pre-test filter calibration value acquisition step, The first calibration value, the fluctuation amount of the first calibration value in the initial stage at the start of the transmission characteristic test (= the second calibration value−the first calibration value), and the transmission characteristic By calibrating the level of the signal received by the signal receiver based on the loss of the variable band-stop filter at the beginning of the test (= the third calibration value−the second calibration value) And a calibration step for performing calibration for measuring the signal level from the mobile communication terminal and testing the transmission characteristics.

  According to the present invention, by adjusting the tuning frequency of the variable band rejection filter 101 in the band rejection filter unit 10, it becomes possible to change the bandwidth and loss amount of the signal to be attenuated. Even when the width is added or changed, it is possible to cope without adding a new filter unit.

  Further, by providing the through-pass 102 in the band rejection filter unit 10, it is possible to individually calculate the calibration value of the path loss of the path excluding the variable band rejection filter 101 and the calibration value regarding the frequency characteristic of the band rejection filter unit 10. Since it becomes possible to calibrate the frequency characteristics of the band rejection filter unit 10 only at the time of calibration performed immediately before the test, the calibration value acquired before the test is performed, particularly the processing related to the frequency setting amount. Costs (calibration value acquisition time) are greatly reduced, and the number of maintenance steps such as filter adjustment (calibration) can be reduced.

It is a conceptual diagram for demonstrating the method of calibration of the signal level in the mobile communication terminal test system which concerns on this embodiment. It is the flowchart which showed the procedure regarding the measurement of the path | pass loss implemented before a test, calculation of a calibration value, and a memory | storage. (A). Is a flowchart in the case of the present invention, (b). Is a flowchart in the case of the conventional method. It is the flowchart which showed the procedure regarding the measurement of path | route loss implemented immediately before implementation of a test, calculation of a calibration value, and a memory | storage. (A). Is a flowchart in the case of the present invention, (b). Is a flowchart in the case of the conventional method. It is an example of the calibration value which calibrates the signal level in the mobile communication terminal test system concerning this invention, and stores this calibration value. It is a figure for demonstrating the influence when the frequency setting used as a test object is added regarding the calibration of the signal level in the mobile communication terminal test system which concerns on this invention. 1 is a system block diagram of a mobile communication terminal test system according to Embodiment 1. FIG. 6 is a system block diagram of a mobile communication terminal test system according to Embodiment 2. FIG. It is an example of a band stop filter unit. It is a conceptual diagram for demonstrating the signal level calibration method in the mobile communication terminal test system which concerns on the conventional system. It is an example of the calibration value which calibrates the signal level in the mobile communication terminal test system which concerns on the conventional system, and stores this calibration value. It is a figure for demonstrating the influence when the frequency setting used as a test object is added regarding the calibration of the signal level in the mobile communication terminal test system which concerns on the conventional system.

  In describing a mode for carrying out the present invention, a mode for performing an interference wave test will be described in the first embodiment, and a mode for performing a transmission test will be described in a second embodiment.

(First Embodiment: Mode for Performing Interference Wave Test)
A mobile communication terminal test system according to the first embodiment and a band rejection filter unit correction method in the mobile communication terminal test system will be described with reference to FIG. In addition, the principal part (functional block) which attached | subjected the code | symbol similar to FIG. 9 in FIG. 1 has the same function.

  The mobile communication terminal test system according to the first embodiment is a test of a mobile communication terminal as a test target, for example, a mobile phone, for testing the specification of the world standard 3GPP, particularly, Chapter 6 of the TS 34.121 standard. This is a conformance test system that realizes an authentication test compliant with (Reception Test), and verifies the anti-jamming wave performance of a mobile communication terminal.

  In the jamming wave test, a jamming wave is generated by a signal generator, and the jamming wave is received by the mobile communication terminal which is the terminal under test, thereby confirming the anti-jamming wave characteristics at the time of reception of the mobile communication terminal. Therefore, it is necessary to perform calibration so that a signal received by a connection connector (connector 15 in FIG. 1) for connecting a mobile communication terminal can obtain a desired output level.

  The signal generator 13 modulates a carrier wave having a specified frequency in a frequency band within a range defined by the mobile communication standard by a predetermined code modulation method and outputs it as a test signal. In the mobile communication terminal test system according to the present embodiment, the signal generator 13 transmits a test signal corresponding to an interference wave, and the test signal passes through an interface unit 11 and a band rejection filter unit 10 which will be described later, and is connected to a connector 15. Is output.

  The interface unit 11 includes a unit 11A and a unit 11B, and each of the unit 11A and the unit 11B can be selected by switching control of a change-over switch that includes a plurality of paths (path A to path M). Has been. In each route from route A to route M, circuit members are incorporated in different configurations for each route to form a network, and necessary routes are selected and switched according to the test to be performed. The switching of the route is controlled by the control unit 12.

  The test signal transmitted by the signal generator 13 is input to one end of the unit 11A of the interface unit 11, and is selected and switched by the control unit 12, and passes through one of the paths M to the other end of the unit 11A. Is output. The test signal output from the unit 11A is input to the band rejection filter unit 10 described later.

  An output signal from the band rejection filter unit 10 is input to one end of the unit 11B of the interface unit 11, and, similarly to the unit 11A, any one of the routes A to M is selected and switched by the control unit 12. Then, it is output to the other end of the unit 11B.

  The band rejection filter unit 10 includes a band rejection variable band rejection filter 101 and a through path 102 that allows a signal to pass through without being attenuated. The band rejection filter unit 10 includes a variable band rejection filter 101 and a through path 102. And can be selectively switched between. The path switching is controlled by the control unit 12 described later.

  The variable band rejection filter 101 has a characteristic in which a frequency fi that resonates when the current to the variable band rejection filter 101 is linearly changed (hereinafter, this frequency is referred to as “tuning frequency”) linearly changes. At least in a frequency band for communication (for example, 500 MHz to 3 GHz), a characteristic (that is, a band rejection characteristic) that attenuates a component of a predetermined frequency bandwidth ΔBW including a tuning frequency fi from a signal input to the filter. Use the filter you have.

  An example of a variable filter used as the variable band rejection filter 101 is YTF (YIG Tuned Filter). As is well known, YTF is a band rejection in which the tuning frequency can be varied using the characteristic that the resonant frequency changes linearly when the DC magnetic field of a YIG (Yttrium Iron Garnet) single crystal is changed linearly. It is a filter. When YTF is used for the variable band rejection filter 101, the DC magnetic field of the YIG single crystal of each variable filter is changed by controlling the current that controls the magnetic field of each variable filter, and the tuning frequency of the filter is changed.

  FIG. 8 is a functional block diagram of a band rejection filter unit showing an example of a variable filter used as the variable band rejection filter 101. As shown in FIG. 8, the band-stop first variable filter 502 (YTF) and the band-stop second variable filter 503 (YTF) connected in series, the first variable filter, and the first variable filter. A band rejection filter unit 50 including a drive unit 501 that independently controls the operations of the two variable filters may be used.

  The signal receiver 14 measures the output level of the received signal. In the present embodiment, during calibration, the test signal transmitted from the signal generator 13 is finally output from the unit 11B of the interface unit 11 through the interface unit 11 and the band rejection filter unit 10, and received as a signal. Is received by the device 14.

  The connector 15 is a terminal for connecting the mobile communication terminal 3 to be tested, and a terminal for inputting and outputting a signal from the outside in order to measure path loss. In the connector 15, the device (or route) connected by the changeover switch 16 is switched. In the present embodiment, a position parallel to the signal receiver 14, that is, the terminal 16a side of the changeover switch 16, is connected, and a part of the signal input to the signal receiver 14 is distributed and output by a distributor (not shown). The Switching of the changeover switch 16 is controlled by a function mode control unit 121 described later.

  The connector 15 is connected to a calibration signal receiver 4 to be described later for calibration before shipment. At this time, the calibration data acquisition control unit 122 described later outputs the output level of the test signal transmitted by the signal generator 13, the output level of the signal received by the calibration signal receiver 4, and the signal received by the signal receiver 14. The calibration value is calculated from the output level and stored in the calibration data memory 123 described later. At the time of the test execution, the correction unit 1241, which will be described later, is connected to the connector 15 so that the mobile communication terminal 3 as a terminal under test can receive a test signal having a desired output level. Is used to calibrate the output level of the test signal transmitted by the signal generator 13.

  The calibration signal receiver 4 is connected to the connector 15 before carrying out the test (before shipment or during adjustment after installing the test system at the user's site or after adjustment of the test system configuration). 15 measure the output level of the test signal. A path loss is obtained from the output level of the test signal measured by the signal receiver for calibration 4, the output level of the test signal measured by the signal receiver 14, and the output level of the signal in the signal generator 13, and calculated as a calibration value. However, even if the signal output level at the connector 15 cannot be directly measured by storing in advance, the signal output level at the connector 15 is calculated from the output level of the signal received by the signal receiver 14 and the calibration value calculated in advance. Can be derived.

  The control unit 12 controls each operation of the signal generator 13, the interface unit 11, the band rejection filter unit 10, the signal receiver 14, and the calibration signal receiver 4, and change of settings for the operation. In addition, the control unit 12 includes a function mode control unit 121 that controls switching of modes according to processing to be executed, a calibration data acquisition control unit 122 that calculates a calibration value necessary for calibration, and a calculated calibration value. Includes a calibration data memory 123 that stores and manages, a correction unit 1241 that calibrates the output level of a signal based on the calibration value, and a test control unit 124 that includes a measurement processing unit 1242 that controls execution of the test.

The processing of the mobile communication terminal test system according to the present invention is classified into a mode for acquiring a calibration value and a mode for executing a test, and the mode for acquiring a calibration value is further different depending on the calibration value to be acquired as follows. (Hereinafter, this mode type is referred to as “calibration mode”).
(Mode 0) Preparation calibration mode (Mode 1) First calibration mode (Mode 2) Second calibration mode

The preparatory calibration mode (mode 0) is a mode in which path loss is calculated in advance before shipment and stored in the calibration data memory 123 as a first calibration value α1 _R (R = A to M; α1 _{A to} α1 _M ).

The first calibration mode (mode 1) and the second calibration mode (mode 2) are operated immediately before the test is performed, and are used mainly for calibrating changes in path loss due to changes in temperature environment and aging. 2 calibration values α2 _R (R = A to M; α1 _{A to} α1 _M ) and third calibration values β _R fx (R = A to M; fx = f1 to fN ′; β _R f1 to β _R fN ′) ) Is calculated and stored in the calibration data memory 123.

  Switching between the mode for obtaining the calibration value and the mode for executing the test and the activation of the components operating in each mode are controlled by the function mode control unit 121.

  The function mode control unit 121 switches according to the mode of the test to be executed (jamming wave test or transmission test) (hereinafter, this mode type is referred to as “measurement mode”) in accordance with the operator's instruction from the user interface 17. The switch 16 is switched to the 16a side in the case of the interference test and to the 16b side in the case of the transmission test.

  In addition, the component to be operated is selectively selected from either the calibration data acquisition control unit 122 or the test control unit 124 in accordance with the processing to be executed (“mode for acquiring calibration value” or “mode for executing test”). Switch to. Further, the user interface 17 notifies the calibration data acquisition control unit 122 or the test control unit 124 of the test condition settings designated by the operator, that is, the frequency settings (f1 to fN ′) for performing the measurement. The condition setting may be acquired sequentially from the user interface 17 when notifying each component (the calibration data acquisition control unit 122 or the test control unit 124), or acquired in advance and stored in a storage area (not shown). A configuration may be adopted in which each component is read from the storage area.

  When the function mode control unit 121 receives an operation instruction in a mode for acquiring a calibration value, the function mode control unit 121 instructs the calibration data acquisition control unit 122 to acquire a calibration value and receives an operation instruction in a mode for executing a test. The test control unit 124 is instructed to execute the test and calibrate the tester.

  The calibration data acquisition control unit 122 measures the output level of the signal at each tester and connector 15 while switching the paths of the band rejection filter unit 10 and the interface unit 11, calculates the path loss of each path, and then performs calibration. The value is stored in the calibration data memory 123 as a value.

  In the description of the path loss calculation in the mobile communication terminal test system according to the present invention, it is assumed that there is no influence of the frequency characteristics of each path in calculating the path loss, and the signal generator 13 and calibration signal generation to be described later are generated. It is assumed that the frequency of the signal transmitted by the device 5 is fixed and the calibration value is obtained from the path loss at that frequency. However, when it is necessary to consider the influence of the frequency characteristics when calculating the path loss, the frequency of the signal transmitted by the signal generator 13 and the calibration signal generator 5 described later is changed for each frequency to be measured. Each path loss is calculated to obtain a calibration value.

  In the mobile communication terminal test system according to the present embodiment, the calibration data acquisition control unit 122 includes the output level of the signal transmitted by the signal generator 13, the output level of the signal received by the signal receiver 14, and the calibration signal. A calibration value is calculated from the output level of the signal received by the receiver 4 and stored in the calibration data memory 123 which is a storage area.

  Hereinafter, a calibration value acquisition method in the preparation calibration mode, the first calibration mode, and the second calibration mode and a tester calibration method in the test execution mode will be specifically described. It is assumed that the calibration data acquisition control unit 122 performs each process described in the following calibration value acquisition method.

(Preparation calibration mode)
First, a preparation calibration mode in which calibration values are calculated and stored in advance before shipment will be described. In the preparatory calibration mode, the calibration signal receiver 4 is connected to the connector 15, and the path loss is calculated for each path in advance before shipment and stored in the calibration data memory 123 as the first calibration value. Specifically, the path loss between the signal generator 13 and the connector 15 is calculated and stored in the calibration data memory 123 as the first calibration value α1 _R (R = A to M; α1 _{A to} α1 _M ). The calculated first calibration value α1 _R (R = A to M; α1 _{A to} α1 _M ) creates a path loss calibration table Tbl1 and stores it in the calibration data memory 123. This procedure is shown in FIG. Will be described with reference to FIG. FIG. These are the flowcharts which showed the procedure regarding the measurement of the path | pass loss performed before shipping, the calculation of a calibration value, and a memory | storage. In FIG. 2 (b). Shows a flowchart of the prior art for comparison.

(Step S101)
The path loss is measured and the calibration value is calculated and stored for all paths (path A to path M) of the interface unit 11. Here, it is assumed that the path loss is measured and the input / output calibration value is calculated while sequentially switching the path from the path A to the path M. First, the path of the interface unit 11 is connected to the path A.

(Step S102)
When measuring the path loss and calculating the calibration value, the path of the band rejection filter unit 10 is switched to the through path 102.

(Step S103)
When the path switching is completed, the path loss is measured and the calibration value is calculated. A signal for calibration is transmitted from the signal generator 13 to the interface unit 11. The calibration signal is output from the interface unit 11 via the unit 11A of the interface unit 11, the through path 102 of the band rejection filter unit 10, and the unit 11B of the interface unit 11, and is distributed by a distributor (not shown) and is received by a signal receiver. 14 and the calibration signal receiver 4 connected to the connector 15.

The path loss between the signal generator 13 and the connector 15 from the output level Dcw of the calibration signal transmitted by the signal generator 13 and the output level Dio of the signal received by the calibration signal receiver 4 at this time. It calculates ΔDio (= Dcw-Dio), stores the path loss calibration table Tbl1 as the first calibration value [alpha] 1 _a. The path loss calibration table Tbl1 is stored in the calibration data memory 123. FIG. Shows an example in which the first calibration value α1 _R (R = A to M; α1 _{A to} α1 _M ) is calculated for each route (route A to route M) and stored in the route loss calibration table Tbl1.

(Step S107)
FIG. As shown, the first calibration value α1 _R (R = A to M; α1 _{A to} α1 _M ) is calculated and stored for each path. If the calculation of the first calibration value α1 _R has not been completed for all the routes (step S105, No), the first calibration value α1 _R is calculated for the switched route by switching to the next route. Do.

(Step S105)
When the first calibration values α1 _R (R = A to M; α1 _{A to} α1 _M ) are calculated for all the routes (step S105, Yes), this processing is terminated.

  Further, the difference between the path loss between the signal generator 13 and the connector 15 and the path loss between the signal generator 13 and the signal receiver 14 is obtained in advance and stored in the calibration data memory 123 as a calibration value L. deep.

The calibration value L obtains the loss between the path between the signal generator 13 and the signal receiver 14 and calculates the difference between the loss between the path between the signal generator 13 and the connector 15 (first calibration value α1 _A ). It is good to ask. Alternatively, the path loss from the connector 15 to the signal receiver 14 may be directly obtained and used as the calibration value L. For the path loss from the connector 15 to the signal receiver 14, a calibration signal generator is connected to the connector 15, a test signal is transmitted from the calibration signal generator and received by the signal receiver 14. It can be calculated from the output level of the signal transmitted from the signal generator for use and the output level of the signal received by the signal receiver 14.

Note that the calibration values (first calibration value α1 _A and calibration value L) in the preparatory calibration mode are not calculated by the calibration data acquisition control unit 122, but the signal generator 13, the signal receiver 14, and the calibration signal. It may be calculated from the output level of the signal in the receiver 4 and stored in the calibration data memory 123 in advance.

  Next, the first calibration mode and the second calibration mode for calculating the calibration value immediately before performing the test will be described. The first calibration mode is a mode for acquiring the second calibration value when the path of the band rejection filter unit 10 is switched to the through path 102, as in the preparation calibration mode, and the second calibration mode is a band calibration mode. This is a mode for acquiring a third calibration value at a desired frequency setting when the path of the stop filter unit 10 is switched to the variable band stop filter 101. When carrying out the test, the mobile communication terminal 3 which is the terminal to be measured is connected to the connector 15. When the mobile communication terminal 3 is connected (or before connection is possible), the path loss is first measured immediately before the test is performed, and the calibration value (the second calibration value and the third calibration value are collectively referred to as “runtime calibration”). Value (sometimes called "value").

  The calibration value at the time of execution is used for correcting the signal level immediately before the test, calibrates an error caused by a change in the temperature environment of the signal generator 13 or aged deterioration, and the output level of the test signal transmitted by the signal generator 13 Used to correct

  This procedure is shown in FIG. Will be described with reference to FIG. FIG. These are the flowcharts which showed the procedure regarding acquisition of the calibration value at the time of execution implemented just before test implementation. In addition, (b). Shows a flowchart of the prior art for comparison.

(Step S301)
The path loss measurement and the calculation of the calibration value at the time of execution are performed by switching the path of the band rejection filter unit 10 to the through path 102 for the path (any one of the path A to the path M) for executing the corresponding test of the interface unit 11. The first calibration mode for obtaining the second calibration value α2 _R and the frequency band (any one of f1 to fN) designated as the condition setting from the user interface 17 after switching to the variable band rejection filter 101 The second calibration mode for acquiring the third calibration value β _R fx is switched and executed. First, the path of the interface unit 11 is connected to the path R (path for executing the corresponding test).

(First calibration mode)
(Step S302)
After switching the path, it switches the path of the band-stop filter unit 10 to the through-pass 102, and calculates the path loss between the set route, is stored in the calibration data memory 123 as a second correction value [alpha] 2 _R. Specifically explaining a method of calculating a second correction value [alpha] 2 _R below.

(Step S303)
A signal for calibration is transmitted from the signal generator 13 to the interface unit 11. The calibration signal is output from the interface unit 11 via the unit 11A of the interface unit 11, the through path 102 of the band rejection filter unit 10, and the unit 11B of the interface unit 11, and is distributed by a distributor (not shown) and is received by a signal receiver. 14 is received.

From the output level Acw of the calibration signal transmitted by the signal generator 13 at this time, the output level A0 of the signal received by the signal receiver 14, and the calibration value L acquired in the preparation calibration mode, the signal generator 13 path loss between the connector 15 and ΔA0 (= Acw-A0 + calibration value L) is calculated and stored in the measurement-time path loss calibration table Tbl2 as the second correction value [alpha] 2 _R. The measurement path loss calibration table Tbl2 is stored in the calibration data memory 123. FIG. 4B. An example stored in the second correction value α2 calculated _R measured during path loss calibration table Tbl2 to.

(Second calibration mode)
(Step S304)
Next, the path of the band rejection filter unit 10 is switched to the variable band rejection filter 101, and the set path and the path loss of the variable band rejection filter 101 are calculated. For the variable band rejection filter 101, the path loss is calculated for the frequency band (fx) for which the test specified as the condition setting from the user interface 17 is performed, and stored in the calibration data memory 123 as the third calibration value β _R fx. To do. A method for calculating the third calibration value β _R fx will be specifically described below. First, the frequency setting of the variable band rejection filter 101 is set to fx.

(Step S305)
As in the first calibration mode, a calibration signal is transmitted from the signal generator 13 to the interface unit 11 and received by the signal receiver 14, and then the calibration signal transmitted by the signal generator 13 at this time is received. The path loss ΔAfx (= Acw−Afx + calibration) between the signal generator 13 and the signal receiver 14 based on the output level Acw of the signal, the output level Afx of the signal received by the signal receiver 14, and the calibration value L. Value L) is calculated and stored in the measurement frequency calibration table Tbl3 as the third calibration value β _R fx. The measurement frequency calibration table Tbl3 is stored in the calibration data memory 123. Thereby, this process is completed. (C) in FIG. Shows an example in which the third calibration value β _R fx is calculated and stored in the measurement frequency calibration table Tbl3.

  The calibration value L is smaller than the loss between the path between the signal generator 13 and the connector 15 and the loss between the path between the signal generator 13 and the signal receiver 14, and is caused by a change in temperature environment, deterioration over time, or the like. Not easily affected. Therefore, it is not necessary to calibrate this every time a test is performed.

Further, when a test is executed for a plurality of frequency settings on the same path (for example, path R), the third calibration value β _R fx may be calculated for the frequency setting, and the second calibration value α 2 _R is calculated for each test. There is no need to calculate. In this case, the measurement frequency calibration table Tbl3 may be expanded to store a plurality of calibration values.

(Calibration method)
Next, a method for calibrating the signal level of the tester related to the band rejection filter unit 10 when executing the test, that is, based on the calibration value calculated in the mode for executing the test will be described. When the operator instructs the execution of the test from the user interface 17, the function mode control unit 121 instructs the test control unit 124 to calibrate the tester and execute the test.

  The test control unit 124 receives the instruction, causes the correction unit 1241 to calibrate the tester, and then instructs the measurement processing unit 1242 to execute the test. The measurement processing unit 1242 passes through the function mode control unit 121. The test specified in the measurement mode is executed in accordance with the test condition setting specified by the operator from the user interface 17.

The correction unit 1241 receives the instruction from the test control unit 124 and calibrates the tester based on the calibration values (α1 _R , α2 _R , β _R fx, and the calibration value L) stored in the calibration data memory 123. Do.

  In the mobile communication terminal measurement system (interference wave test) according to the present embodiment, the correction unit 1241 sets the output level of the signal transmitted by the signal generator 13 so that the connector 15 can obtain a signal of a desired output level. Calibrate.

  The calibration method will be specifically described below, taking as an example a case where the path of the interface unit 11 is connected to the path A and set to the frequency setting f1 of the variable band rejection filter 101. Note that the correction unit 1241 performs each process described in the following calibration method.

For the calibration of the output level of the signal transmitted by the signal generator 13, the first calibration value α 1 _A indicating the inter-path loss between the signal generator 13 and the connector 15 is used. However, since the calculation of the first calibration value α1 _A does not take into account the frequency characteristics of the variable band rejection filter 101 and the influence of errors caused by changes in the temperature environment, aging, etc., the second calibration value Calibration is performed using α2 _A and the third calibration value β _A f1.

First, a calibration value γ1 _A that calibrates an error in the amount of loss generated between the signal generator 13 and the connector 15 due to a change in temperature environment, aging, or the like is a first calibration value calculated before the test is performed. and [alpha] 1 _a, it is determined as follows from the second correction value [alpha] 2 _a calculated immediately before the test.

(Calibration value γ1 _A ) = (second calibration value α2 _A ) − (first calibration value α1 _A )

Further, a calibration value γ2 _Af1 for calibrating the loss amount in the variable band rejection filter 101 is a path loss including a circuit network constituted by the path A and the variable band rejection filter 101 when the frequency setting is f1, that is, a third value. From the calibration value β _A f1 and the path loss of only the circuit network configured by the path A (when the band rejection filter unit 10 is connected to the through path 102), that is, the second calibration value α2 _A , Ask.

(Calibration value γ2 _Af1 ) = (Third calibration value β _A f1) − (Second calibration value α2 _A )

  From the above, the output level of the signal transmitted by the signal generator 13 (calibrated by the calibration value) is Pio, the desired output level to which the signal at the connector 15 should be output is P0, and the output of the signal received by the signal receiver 14 is output. When the level is P1, the output level Pio of the signal transmitted by the signal generator 13 during the test is calibrated as follows to calibrate the loss between the path between the signal generator 13 and the connector 15, and the connector 15 A signal having a desired output level can be obtained.

(Output level Pio)
= (Output level P0) + (Calibration value γ1 _A ) + (Calibration value γ2 _Af1 )
= (Output level P1) + (Calibration value L) + (Calibration value γ1 _A ) + (Calibration value γ2 _Af1 )
= (Output level P1) + (Calibration value L)
+ {(Second calibration value α2 _A ) − (first calibration value α1 _A )}
+ {(Third calibration value β _A f1) − (Second calibration value α2 _A )}

Example 1
An example of a mobile communication verification apparatus according to the first embodiment and a band rejection filter correction method in the mobile communication verification apparatus will be described with reference to FIG. FIG. 6 is a system block diagram illustrating only the interference wave test using the mobile communication terminal test system according to the present embodiment.

  The signal generator 13a outputs a continuous wave signal, that is, an unmodulated signal set in 1 MHz steps in a frequency band to be measured (for example, 1 MHz to 12.75 GHz) as an interference wave for the pseudo base station signal wave. . The signal generator 13a corresponds to the signal generator 13 in FIG.

  The band rejection filter 10a passes only frequency components other than the frequency band of the pseudo base station signal output from the signal transmission unit 201 among the frequency components of the continuous wave signal output from the signal generator 13a, and transmits the pseudo base station signal. Only the component corresponding to the frequency band of is suppressed. In other words, it is desirable to have a flat frequency characteristic in which the frequency band of the pseudo base station signal is greatly attenuated and the passage loss other than the attenuation band is small. The band rejection filter 10a corresponds to the band rejection filter unit 10 in FIG.

  The pseudo base station 20 includes a signal transmission unit 201 that transmits a pseudo base station signal to the mobile communication terminal 3 and a signal reception unit 202 that receives and demodulates a response signal from the mobile communication terminal 3.

  The signal transmission unit 201 modulates a carrier wave having a designated frequency in a frequency band in a range defined in the standard by a predetermined code modulation method, and outputs the modulated base station signal.

  The signal receiving unit 202 receives a response signal from the mobile communication terminal 3 that is a terminal under test, and uses a predetermined frequency demodulation carrier (corresponding to the code modulation method used by the signal transmission unit 201). Demodulate by code demodulation method. By measuring the signal demodulated by the signal receiving unit 202, it is possible to confirm that the mobile communication terminal 3 has correctly received the pseudo base station signal transmitted by the signal transmitting unit 201.

  The directional coupler 21 is a broadband coupler that allows the output frequency of the signal generator 13a to pass through. The directional coupler 21 synthesizes the interference wave from the signal generator 13a with the pseudo base station signal wave from the signal transmission unit 201, and will be described later. Output to the distributor 22.

  The circulator 26 sends a signal from the directional coupler 21 toward the mobile communication terminal 3 and sends a signal from the mobile communication terminal 3 toward the signal receiving unit 202.

  The distributor 22 distributes and outputs the received signal to a connector 15 and a signal receiver 14a described later. Further, the signal received from the connector 15 is output as it is to the circulator 26 side without being distributed.

  The connector 15 is a connector for inputting / outputting a signal to / from the mobile communication terminal test system according to the present embodiment, and corresponds to the connector 15 in FIG. In the interference wave test, when a calibration value is acquired before the test is performed (before shipping, etc.), the signal output level is measured after a calibration signal receiver 4 described later is connected. During the test, the mobile communication terminal 3 which is the terminal to be measured is connected, and the anti-jamming wave characteristics of the mobile communication terminal 3 are measured.

  The mobile communication terminal 3 is a terminal under test, receives a base station signal from a pseudo base station 20 to be described later, and transmits a response signal to the pseudo base station 20. The mobile communication terminal 3 corresponds to the mobile communication terminal 3 in FIG.

  The calibration signal receiver 4 is connected to the connector 15 before the test is executed (before shipping, etc.), and measures the output level of the signal transmitted from the signal generator 13a at the connector 15. A path loss is measured from the output level of the signal obtained by the measurement, and a calibration value used for calibration of the band rejection filter 10a is calculated. The calibration signal receiver 4 corresponds to the calibration signal receiver 4 in FIG.

  The signal receiver 14a is a signal measuring device that measures the output level of the received signal, and corresponds to the signal receiver 14 in FIG.

  The received signal measuring unit 23 receives the signal demodulated by the signal receiving unit 202, measures a bit error rate (BER) that estimates the degree of the influence of the interference wave, and outputs the result. The reception signal measuring unit 23 for measuring the bit error rate is well known to those skilled in the art and is not directly related to the present invention, and thus detailed description thereof is omitted.

  A circuit network including the pseudo base station 20, the directional coupler 21, the circulator 26, the distributor 22, the received signal measuring unit 23, and the wiring connecting the functional blocks is the path of the interface unit 11 in FIG. It corresponds to one.

(Second Embodiment: Mode for Performing Transmission Test)
A mobile communication terminal test system according to a second embodiment and a band rejection filter unit correction method in the mobile communication terminal test system will be described with reference to FIG. FIG. 1 is a conceptual diagram for explaining a method of correcting a band rejection filter unit in the mobile communication terminal test system according to the present embodiment. In addition, the principal part (functional block) which attached | subjected the code | symbol similar to FIG. 9 in FIG. 1 has the same function.

  The mobile communication terminal test system according to the second embodiment is used to test a mobile communication terminal as a test target, for example, a mobile phone, in accordance with the specifications of the world standard 3GPP, in particular, Chapter 5 of TS 34.121 standard. This is a conformance test system that realizes an authentication test compliant with (Transmission Test), and verifies compliance with a standard with respect to spurious included in a response signal from a mobile communication terminal.

  Regarding the configuration of the mobile communication terminal test system according to the present embodiment, the description of the same configuration as the first embodiment will be omitted, and only the different configuration will be described.

  In the mobile communication terminal test system according to the present embodiment, the mobile communication terminal 3 to be measured is connected to the connector 15, the signal transmitted from the mobile communication terminal 3 is received by the signal receiver 14, and the signal is received. Measure the included spurious. Therefore, the connector 15 is connected to the signal generator 13 in parallel, that is, to the terminal 16b side of the changeover switch 16, and the signal input to the connector 15 is input to the interface unit 11 via a directional coupler (not shown). Is done.

  The connector 15 is connected to a calibration signal generator 5 described later before shipment. At this time, the calibration data acquisition control unit 122 instructs the calibration signal generator 5 to transmit a calibration signal to the signal receiver 14, and the output level of the signal transmitted by the calibration signal generator 5. Then, the path loss is calculated from the output level of the test signal measured by the signal receiver 14 and the output level of the signal from the signal generator 13 and stored in the calibration data memory 123 as a calibration value.

  In the mobile communication terminal test system according to the present embodiment, the control unit 12 includes operations of the signal generator 13, the interface unit 11, the band rejection filter unit 10, the signal receiver 14, and the calibration signal generator 5, and Control changes in settings to work.

  In the mobile communication terminal test system according to the present embodiment, switching is made to the 16b side.

  In the mobile communication terminal test system according to the present embodiment, the calibration data acquisition control unit 122 includes the output level of the signal transmitted by the signal generator 13, the output level of the signal received by the signal receiver 14, and the calibration signal. A calibration value is calculated from the output level of the signal transmitted by the generator 5 and stored in the calibration data memory 123. FIG. 2A shows a calibration value acquisition method in the preparation calibration mode, the first calibration mode, and the second calibration mode, and the tester calibration method in the test execution mode. And FIG. 3 (a). It demonstrates concretely with reference to.

  Note that the procedure for acquiring the calibration value by switching the path before shipment and immediately before the test is the same as that of the mobile communication terminal test system according to the first embodiment, so the description is omitted and the procedure is different. Only the portion related to the measurement of the path loss and the calculation of the calibration value (steps S103, S303, and S305) will be described. In addition, each process described in the following calibration value acquisition method is performed by the calibration data acquisition control unit 122.

(Preparation calibration mode)
(Step S103)
Before the test (before shipping, etc.), the path loss for each path (path A to path M) is measured and the first calibration value α1 _R (R = A to M; similar to the first embodiment). α1 _{A to} α1 _M ) is calculated. First, a calibration signal is transmitted from the calibration signal generator 5 to the interface unit 11. The calibration signal is output from the interface unit 11 via the unit 11B of the interface unit 11, the through path 102 of the band rejection filter unit 10, and the unit 11A of the interface unit 11, and is distributed by a distributor (not shown) to be a signal receiver. 14 is received.

The calibration signal generator 5 and the signal reception are obtained from the output level D′ io of the calibration signal transmitted by the calibration signal generator 5 and the output level D′ sa of the signal received by the signal receiver 14 at this time. calculating a path loss ΔD'sa (= D'sa-D'io) between the vessel 14, and stores the path loss calibration table Tbl1 as the first calibration value [alpha] 1 _R. FIG. Shows an example in which the first calibration value α1 _R (R = A to M; α1 _{A to} α1 _M ) is calculated for each route (route A to route M) and stored in the route loss calibration table Tbl1. As described above, the first calibration value α1 _R is acquired for all routes (route A to route M).

  The difference between the path loss between the connector 15 and the signal receiver 14 and the path loss between the signal generator 13 and the signal receiver 14 is obtained in advance and stored in the calibration data memory 123 as a calibration value L. deep.

The calibration value L calculates the loss between the path between the signal generator 13 and the signal receiver 14 and calculates the difference between the loss between the path between the connector 15 and the signal receiver 14 (first calibration value α1 _A ). It is good to ask. Alternatively, the path loss from the connector 15 to the signal receiver 14 may be directly obtained and used as the calibration value L. For the path loss from the connector 15 to the signal receiver 14, a calibration signal generator is connected to the connector 15, a test signal is transmitted from the calibration signal generator and received by the signal receiver 14. It can be calculated from the output level of the signal transmitted from the signal generator for use and the output level of the signal received by the signal receiver 14.

(Second calibration mode)
(Step S303)
Immediately before the test is performed, as in the first embodiment, the mobile communication terminal 3 that is the terminal to be measured is connected (or may be before connection), and the path for executing the corresponding test (path A to path) the second calibration value measured path loss for any) of M [alpha] 2 to calculate the _R and the third correction value beta _R fx.

First, by switching the path of the band-stop filter unit 10 to the through-pass 102, to measure a path loss between the set route, to calculate a second correction value [alpha] 2 _R. A signal for calibration is transmitted from the signal generator 13 to the interface unit 11. The calibration signal is output from the interface unit 11 and received by the signal receiver 14 via the unit 11A of the interface unit 11, the through path 102 of the band rejection filter unit 10, and the unit 11B of the interface unit 11.

From the output level A′cw of the calibration signal transmitted by the signal generator 13 at this time, the output level A′0 of the signal received by the signal receiver 14, and the calibration value L acquired in the preparation calibration mode, path loss between the signal generator 13 and signal receiver 14 ΔA'0 (= A'cw-A'0 + calibration value L) is calculated, the measurement time path loss calibration table Tbl2 as the second correction value [alpha] 2 _R To remember. The measurement path loss calibration table Tbl2 is stored in the calibration data memory 123. FIG. 4B. Shows an example in which each second calibration value α2 _R is calculated and stored in the measurement path loss calibration table Tbl2.

(Step S305)
Next, the path of the band rejection filter unit 10 is switched to the variable band rejection filter 101, and the set path and the path loss of the variable band rejection filter 101 are calculated. For the variable band rejection filter 101, the path loss is calculated for the frequency band (fx) for which the test specified as the condition setting from the user interface 17 is performed, and the third calibration value β _R fx is stored in the calibration data memory 123. Remember.

As in the first calibration mode, a calibration signal is transmitted from the signal generator 13 to the interface unit 11 and received by the signal receiver 14, and then the calibration signal transmitted by the signal generator 13 at this time is received. The path loss ΔA′fx between the signal generator 13 and the signal receiver 14 from the output level A′cw of the signal, the output level A′fx of the signal received by the signal receiver 14, and the calibration value L. (= A′cw−A′fx + calibration value L) is calculated and stored in the measurement frequency calibration table Tbl3 as the third calibration value β _R fx. The measurement frequency calibration table Tbl3 is stored in the calibration data memory 123. This is the end of this process. (C) in FIG. Shows an example in which the third calibration value β _R fx is calculated and stored in the measurement frequency calibration table Tbl3.

  The calibration value L is smaller than the loss between the path between the signal generator 13 and the connector 15 and the loss between the path between the signal generator 13 and the signal receiver 14, and is caused by a change in temperature environment, deterioration over time, or the like. Not easily affected. Therefore, it is not necessary to calibrate this every time a test is performed.

Further, when a test is executed for a plurality of frequency settings on the same path (for example, path R), the third calibration value β _R fx may be calculated for the frequency setting, and the second calibration value α 2 _R is calculated for each test. There is no need to calculate. In this case, the measurement frequency calibration table Tbl3 may be expanded to store a plurality of calibration values.

(Calibration method)
Next, a method for calibrating the signal level of the tester related to the band rejection filter unit 10 when executing the test, that is, based on the calibration value calculated in the mode for executing the test will be described. In the mobile communication terminal measurement system (transmission test) according to the present embodiment, the correction unit 1241 receives the signal receiver 14 in order to confirm that a signal of a desired output level is transmitted from the connector 15. Correct the output level of the selected signal.

  The calibration method will be specifically described below, taking as an example a case where the path of the interface unit 11 is connected to the path A and set to the frequency setting f1 of the variable band rejection filter 101. Note that the correction unit 1241 performs each process described in the following calibration method.

For correcting the output level of the signal received by the signal receiver 14, the first calibration value α1 _A indicating the loss between paths between the connector 15 and the signal receiver 14 is used. However, since the calculation of the first calibration value α1 _A does not take into account the frequency characteristics of the variable band rejection filter 101 and the influence of errors caused by changes in the temperature environment, aging, etc., the second calibration value Calibration is performed using α2 _A and the third calibration value β _A f1.

First, a calibration value γ1 _A for calibrating an error in the amount of loss generated between the signal generator 13 and the signal receiver 14 due to a change in temperature environment, aging deterioration, or the like is calculated using the first From the calibration value α1 _A and the calibration value L and the second calibration value α2 _A calculated immediately before the test, it is obtained as follows.

(Calibration value γ1 _A ) = (second calibration value α2 _A ) − (first calibration value α1 _A )

Further, a calibration value γ2 _Af1 for calibrating the loss amount in the variable band rejection filter 101 is a path loss including a circuit network constituted by the path A and the variable band rejection filter 101 when the frequency setting is f1, that is, a third value. From the calibration value β _A f1 and the path loss of only the circuit network configured by the path A (when the band rejection filter unit 10 is connected to the through path 102), that is, the second calibration value α2 _A , Ask.

(Calibration value γ2 _Af1 ) = (Third calibration value β _A f1) − (Second calibration value α2 _A )

  From the above, the output level of the signal received by the signal receiver 14 (corrected by the calibration value) is Pio, the desired output level to which the signal at the connector 15 should be output is P0, and the signal transmitted by the signal generator 13 is Assuming that the output level is P1, by correcting the output level Pio of the signal received by the signal receiver 14 during the test as follows, the loss between the path between the signal generator 13 and the connector 15 is calibrated. It is possible to confirm that a signal having a desired output level is output from 15.

(Output level P0) = (Output level P1)-(Calibration value L)
= (Output level Pio) + (Calibration value γ1 _A ) + (Calibration value γ2 _Af1 )
(Output level Pio)
= (Output level P0) − (Calibration value γ1 _A ) − (Calibration value γ2 _Af1 )
= (Output level P1)-(Calibration value L)-(Calibration value γ1 _A )-(Calibration value γ2 _Af1 )
= (Output level P1)-(Calibration value L)
-{(Second calibration value α2 _A )-(first calibration value α1 _A )}
− {(Third calibration value β _A f1) − (second calibration value α2 _A )}

(Example 2)
An example of a mobile communication verification apparatus according to the second embodiment and a band rejection filter correction method in the mobile communication verification apparatus will be described with reference to FIG. FIG. 7 is a system block diagram illustrating only a transmission test using the mobile communication terminal test system according to the present embodiment.

  In this test, the influence of spurious included in the response signal is verified by receiving the pseudo base station signal transmitted from the pseudo base station 20 and measuring the response signal returned by the mobile communication terminal 3 as the terminal under test. Since the configurations and operations of the pseudo base station 20 including the signal transmission unit 201 and the signal reception unit 202 and the mobile communication terminal 3 according to the present embodiment are the same as those of the mobile communication terminal test system according to the first embodiment, description will be made. Is omitted.

  The connector 15 is a connector for inputting / outputting a signal to / from the mobile communication terminal test system according to the present embodiment, and corresponds to the connector 15 in FIG. In the transmission test, when a calibration value is acquired before the test is performed (before shipping, etc.), a signal output level is measured after a calibration signal generator 5 described later is connected. At the time of performing the test, after connecting the mobile communication terminal 3 which is a terminal to be measured, a signal is transmitted from the mobile communication terminal 3 and received by a received signal measuring unit 14b described later to measure spurious contained in the signal. Do.

  The calibration signal generator 5 is connected to the connector 15 before executing a test (before shipment or the like), and transmits a test signal to the reception signal measuring unit 14b. At this time, the path loss between the calibration signal generator 5 and the received signal measuring unit 14b is determined from the output level of the signal transmitted by the calibration signal generator 5 and the output level of the signal received by the received signal measuring unit 14b. And a calibration value used for calibration of the band rejection filter 10a is calculated. The calibration signal generator 5 corresponds to the calibration signal generator 5 in FIG.

  The signal generator 13b transmits a test signal to the received signal measuring unit 14b described later. At this time, the path loss between the signal generator 13b and the received signal measuring unit 14b is measured from the output level of the signal transmitted by the signal generator 13b and the output level of the signal received by the received signal measuring unit 14b. A calibration value used for calibration of the blocking filter 10a is calculated. The signal generator 13b corresponds to the signal generator 13 in FIG.

  The directional coupler 24 is a wideband that passes the output signal of the signal generator 13b and the signal input from the connector 15, that is, the output frequency of the output signal of the calibration signal generator 5 and the mobile communication terminal 3. It is a combiner and outputs the output signal of the signal generator 13b and the signal input from the connector 15 only to the circulator 26 side. Further, a signal input from the circulator 26 side is output only to the connector 15.

  The splitter 25 demultiplexes the response signal wave from the mobile communication terminal 3 or the test signal wave transmitted from the signal generator 13b or the calibration signal generator 5, and performs signal reception unit 202 and reception signal measurement described later. Input to both of the parts 14b.

  The band rejection filter 10b passes only frequency components other than the frequency band corresponding to the carrier of the response signal wave among the frequency components of the response signal wave input to the received signal measuring unit 14b, and corresponds to the carrier of the response signal. Suppresses frequency band components. In other words, it is desirable to have a flat frequency characteristic in which the frequency band corresponding to the carrier of the response signal is greatly attenuated, and the band other than the attenuation band has a small passage loss. The band rejection filter 10b corresponds to the band rejection filter unit 10 in FIG.

  The received signal measurement unit 14b calculates the input / output calibration value at the time of calibration of the band rejection filter 10b, that is, before the test (before shipping, etc.) and when the runtime calibration value is calculated immediately before the test. Measure the output level of the received signal. The received signal measuring unit 14b corresponds to the signal receiver 14 in FIG.

  The received signal measuring unit 14b measures the signal level of each frequency component included in the response signal from the mobile communication terminal 3 that is the terminal under test, and confirms that these values are equal to or less than a specified value.

  The response signal from the mobile communication terminal 3 input to the received signal measuring unit 14b is attenuated in the frequency band component corresponding to the carrier of the response signal by the band rejection filter 10b. It is possible to measure only the spurious.

As described above, in the mobile communication terminal test system according to the present invention, the calibration values (α1 _R , α2 _R ,...) Performed before the test and immediately before the test are performed as the calibration related to the band rejection filter unit 10. And the processing cost for calculating β _R fx) is calculated by the following calculation formula.

(Processing cost for obtaining calibration values before test (before shipment))
= (Number of times the first calibration value α1 _R is calculated)
= 1 x M

Here, FIG. 5 shows a calibration table when a frequency setting to be tested is added with respect to signal level calibration in the mobile communication terminal test system according to the present invention. As can be seen from the fact that the calibration table shown in FIG. 5 is the same as the calibration table shown in FIG. 4, in the mobile communication terminal test system according to this embodiment, the calibration value (α1 ′ _R in the conventional method) is used. Compared to the processing cost related to the calculation of fx), the processing cost related to the frequency setting amount of the calibration value (first calibration value α1 _R ) acquired before the test is significantly reduced.

(Add frequency setting)
In addition, the effect of reducing the processing cost is prominent even when a frequency setting to be measured is added (for example, due to the addition or change of a standard). Hereinafter, the processing when the frequency setting to be measured is added will be described assuming that the frequencies fa1 to fan are added as the frequency setting.

In the conventional system, a band rejection type fixed filter corresponding to the frequency setting (frequency fa1 to fan) to be added to the band rejection filter unit 10C is connected, and before the test (before shipment or test) for the added frequency setting. It is necessary to calculate a calibration value (α1 ′ _R fx) to be calculated at the time of adjustment after installing the system at the user's site or at the time of adjustment after changing the test system configuration.

  On the other hand, in the mobile communication terminal test system according to the present invention, since the variable band rejection filter 101 is used, it is only necessary to add the frequency setting (frequency fa1 to fan) to be added. There is no need to connect.

In addition, since the first calibration value α1 _R and the second calibration value α2 _R do not have parameters depending on the frequency setting, it is not necessary to calculate a new calibration value, and the first calibration value α1 _R and the second calibration value α2 _R are connected to the variable band rejection filter 101 immediately before the test is performed. However, it is only necessary to calculate the third calibration value β _R fx for the frequency setting for performing the test, and the processing cost for calculating the calibration value due to the addition of the frequency setting does not occur.

  For this reason, in the mobile communication terminal test system according to the present invention, the processing cost for calculating the calibration value accompanying the addition of the frequency setting is greatly reduced compared to the conventional method.

  Note that FIG. And FIG. 3 (b). As is clear from the comparison, the mobile communication terminal test system of the present invention increases the number of times of calibration value acquisition in the calibration immediately before the test execution by one as compared with the conventional test system. However, the time required for obtaining one calibration value is extremely shorter than the time required for the interference wave test and the transmission test. Therefore, there is no influence of an increase in test time on a user who uses the mobile communication terminal test system of the present invention.

  In addition, the first and second embodiments specifically explain the system configuration of each test (interference wave test and transmission test). By integrating the system configurations of the first and second embodiments, FIG. The configuration shown in FIG.

DESCRIPTION OF SYMBOLS 3 Mobile communication terminal 4 Calibration signal receiver 5 Calibration signal generator 10, 10C Band stop filter unit 10a, 10b Band stop filter 11 Interface unit 12 Control unit 13, 13a, 13b Signal generator
14, 14a Signal receiver 14b Received signal measuring unit 15 Connector 20 Pseudo base station 21 Directional coupler 22 Divider 23 Received signal measuring unit 24 Directional coupler 25 Splitter 26 Circulator
DESCRIPTION OF SYMBOLS 50 Filter unit 101 Variable band rejection filter 102 Through-pass 121 Function mode control part 122 Calibration data acquisition control part 123 Calibration data memory 124 Test control part 201 Signal transmission part 202 Signal reception part 501 Drive part 502 1st variable filter 503 2nd Variable filter 1241 Correction unit 1242 Measurement processing unit

Claims (5)

A signal generator (13), a signal receiver (14), a connector (15) for connection to a mobile communication terminal, and a band rejection filter unit (10) for attenuating a signal in a desired frequency band In order to perform a predetermined test of the mobile communication terminal, the predetermined test is performed by switching each path between the signal generator, the signal receiver, the connector, and the band rejection filter unit. A switching interface unit (11) for performing a predetermined test of the mobile communication terminal using the signal generator or the signal receiver as a tester,
The band rejection filter unit includes a variable band rejection filter (101) configured by a YTF and attenuating the signal of the desired frequency band by setting the tuning frequency of the YTF to a predetermined frequency, and the desired frequency band. A through-pass (102) that allows the signal to pass through without being attenuated, and is configured to be able to select either the variable band-stop filter or the through-pass.
The path loss of each path between the tester and the connector when the path is switched by the switching interface unit in a state where the band rejection filter unit is selected in advance is a first calibration value (α1 _A ,..., Α1 _M ) to be stored as a calibration data memory (123);
Initially at the start of the predetermined test, the band rejection filter unit selects the through path, and the switching interface unit performs the predetermined test with the tester and the connector. The path loss is measured and stored as a second calibration value (α2 _R ), and the tuning frequency is set to the frequency corresponding to the predetermined test in the band rejection filter unit while the path remains unchanged. A calibration data acquisition controller (122) for measuring a path loss between the tester and the connector when the variable band rejection filter is selected and storing it as a third calibration value (β _R fx); ,
When the predetermined test is a reception characteristic test of the mobile communication terminal, the output level of the signal generator used as the tester is determined by the transmission characteristic test of the mobile communication terminal. In some cases, a test for performing the predetermined test by calibrating the reception level of the signal receiver used as the tester with the first calibration value, the second calibration value, and the third calibration value. A mobile communication terminal test system comprising a control unit (124).   The test control unit inputs a signal from the signal generator to the mobile communication terminal via the connector via the path and the band rejection filter unit, and sets the reception characteristics of the mobile communication terminal. When testing, the first calibration value, the amount of fluctuation of the first calibration value at the beginning of the reception characteristic test (= the second calibration value−the first calibration value), and The level of the signal output by the signal generator based on the loss of the variable band rejection filter at the beginning of the reception characteristic test (= the third calibration value−the second calibration value) The mobile communication terminal test system according to claim 1, wherein a signal of a desired level is supplied to the mobile communication terminal for testing by calibrating the mobile communication terminal.   The test control unit receives a signal from the mobile communication terminal via the connector via the path and the band rejection filter unit via the connector by the signal receiver and receives the signal from the mobile communication terminal. When the transmission characteristics of the first and second transmission characteristics are tested, the first calibration value and the variation of the first calibration value at the beginning of the transmission characteristics test (= the second calibration value−the first calibration value). Calibration signal) and the loss of the variable band rejection filter at the beginning of the transmission characteristic test (= the third calibration value−the second calibration value). The mobile communication terminal test system according to claim 1, wherein the level of the signal from the mobile communication terminal is measured and tested by calibrating the level of the signal to be received. A signal generator (13), a signal receiver (14), a connector (15) for connection to a mobile communication terminal, and a band rejection filter unit (10) for attenuating a signal in a desired frequency band A configuration for performing the predetermined test by switching each path between the signal generator, the connector, the signal receiver, and the band rejection filter unit in order to perform a predetermined test of the mobile communication terminal; And a switching interface unit (11) for performing the predetermined test of the mobile communication terminal using the signal generator or the signal receiver as a tester. ,
The band rejection filter unit includes a variable band rejection filter (101) configured by a YTF and attenuating the signal of the desired frequency band by setting the tuning frequency of the YTF to a predetermined frequency, and the desired frequency band. A through-pass (102) that allows the signal to pass through without being attenuated, and is configured to be able to select either the variable band-stop filter or the through-pass.
The path loss of each path between the tester and the connector when the path is switched by the switching interface unit in a state where the band rejection filter unit selects the through path in advance is a first calibration value (α1 _A ,..., Α1 _M )
If the predetermined test is a test of the reception characteristic of the mobile communication terminal, the initial at the start of the test of the reception characteristics, by selecting the ball for the band stop filter unit, said by the switching interface unit A path loss between the tester and the connector when the path is configured to test the reception characteristic and the signal receiver is configured to be connected to the mobile communication terminal in parallel with the path to the connector Measuring and storing as a second calibration value (α2 _R ) a pre-test path calibration value acquisition step;
After the pre-test path calibration value acquisition step, the band rejection filter unit is allowed to select the variable band rejection filter in which the tuning frequency is set to a frequency corresponding to the predetermined test while the path remains unchanged. A pre-test filter calibration value acquisition step of measuring a path loss between the tester and the connector and storing it as a third calibration value (β _R fx);
After the pre-test filter calibration value acquisition step, the fluctuation amount of the first calibration value at the beginning of the test of the first calibration value and the reception characteristic (= the second calibration value−the first calibration value). ) And the loss of the variable band rejection filter at the beginning of the reception characteristic test (= the third calibration value−the second calibration value), the signal generator A calibration method comprising: a calibration step for calibrating the level of a signal to be output to supply a signal of a desired level to the mobile communication terminal to test the reception characteristic. A signal generator (13), a signal receiver (14), a connector (15) for connection to a mobile communication terminal, and a band rejection filter unit (10) for attenuating a signal in a desired frequency band A configuration for performing the predetermined test by switching each path between the signal generator, the connector, the signal receiver, and the band rejection filter unit in order to perform a predetermined test of the mobile communication terminal; And a switching interface unit (11) for performing the predetermined test of the mobile communication terminal using the signal generator or the signal receiver as a tester. ,
The band rejection filter unit includes a variable band rejection filter (101) configured by a YTF and attenuating the signal of the desired frequency band by setting the tuning frequency of the YTF to a predetermined frequency, and the desired frequency band. A through-pass (102) that allows the signal to pass through without being attenuated, and is configured to be able to select either the variable band-stop filter or the through-pass.
The path loss of each path between the tester and the connector when the path is switched by the switching interface unit in a state where the band rejection filter unit selects the through path in advance is a first calibration value (α1 _A ,..., Α1 _M )
When the predetermined test is a test of transmission characteristics of the mobile communication terminal, at the beginning of the test of the transmission characteristics, the band rejection filter unit selects the through path, and the switching interface unit A pre-test path calibration value acquisition step for configuring a path to test the transmission characteristic and measuring a path loss between the tester and the connector and storing the path loss as a second calibration value (α2 _R );
After the pre-test path calibration value acquisition step, the band rejection filter unit is allowed to select the variable band rejection filter in which the tuning frequency is set to a frequency corresponding to the predetermined test while the path remains unchanged. A pre-test filter calibration value acquisition step of measuring a path loss between the tester and the connector and storing it as a third calibration value (β _R fx);
After the pre-test filter calibration value acquisition step, the first calibration value and the variation of the first calibration value at the beginning of the test of the transmission characteristic (= the second calibration value−the first ) And the loss of the variable band rejection filter at the beginning of the transmission characteristic test (= the third calibration value−the second calibration value), the signal receiver A calibration method comprising: a calibration step of performing calibration for measuring the signal level from the mobile communication terminal and performing the test of the transmission characteristic by calibrating the level of the signal to be received.