JP2008017131A - Device measuring device for mobile terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily control a device to be measured. <P>SOLUTION: In the device measuring device for a mobile terminal which has a control unit 33 controlling a measurement signal generator 21 and a control signal generator 22 according to operation to an operation unit 31 to supply a measurement signal and a control signal to the device 1 to be measured, and also making a display unit 32 display a processing result of a signal analyzing unit 23, the control unit 33 is provided with a control sequence generating means 110 of allowing control commands defined for the device 1 to be measured to be selected and specified in arbitrary order on the screen of the display unit 32 and registering the selected and specified control command group as one control sequence. Consequently, the registered control sequence is displayed by the display unit 32 to be selected and specified through operation to the operation unit 31, and the control sequence can be executed by being specified at the operation unit 31. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a technique for easily measuring a device used in a mobile terminal such as a mobile phone or a PDA.

  Devices used for portable terminals such as cellular phones and PDAs have been highly functional and integrated year by year, and now, as shown in FIG. 19, a switch for switching antennas for transmission and reception and amplification of transmission signals A front end unit 11 configured by an amplifier and the like, and a frequency conversion that converts a baseband signal into a high-frequency signal and outputs the high-frequency signal to the front-end unit 11 and converts a reception signal output from the front-end unit 11 into a baseband signal Control unit 12, front end unit 11, and frequency conversion unit 12, and a transmission baseband signal including information such as voice and data is given to frequency conversion unit 12, and the baseband output from frequency conversion unit 12 It has a three-chip configuration with an application unit 13 that demodulates audio and data based on the signal.

  Here, the frequency conversion unit 12 is configured to be multiband or multimode so as to be compatible with a plurality of frequency bands (800 MHz, 2 GHz, 2.5 GHz, etc.) and communication systems (WCDMA, GSM, etc.) used by the mobile terminal. Has been.

  In the future, further integration and miniaturization will progress, and it is expected that the front end unit 11 and the frequency conversion unit 12 will be integrated to form a two-chip configuration.

  By the way, in the device development department as described above, it is necessary to measure the characteristics of the device under development while arbitrarily changing various parameters. For example, there are measurement items such as power (Pout), spurious, modulation error (EVM), adjacent channel leakage power (ACPR), and carrier leak for transmission, and gain, intermodulation (IM), baseband modulation for reception. There are items such as error (IQEVM).

  When performing various measurements on the devices as described above, the signal generator, spectrum analyzer, baseband signal generator, baseband signal demodulator, power supply, etc. required for measurement have been prepared in the past. The devices are manually operated, and each device is remotely controlled from an external computer.

  For example, Patent Document 1 is known as an apparatus dedicated for testing devices such as ICs.

JP-A-6-273488

  However, in the conventional device measuring apparatus that has been realized so far, there is no device that can easily and efficiently set the control of the device under measurement and its procedure, etc. Was very inconvenient.

  An object of the present invention is to solve this problem and provide a device measuring apparatus for a portable terminal that can easily control a device under measurement.

In order to achieve the above object, a device measuring apparatus for a portable terminal of the present invention comprises:
A measurement signal generator (21) for generating a measurement signal to be given to a device under test for a portable terminal;
A control signal generator (22) for generating a control signal to be given to the device under measurement;
A signal analysis unit (23) for performing an analysis process of an output signal of the device under measurement;
An operation unit (31);
A display unit (32);
The measurement signal generation unit and the control signal generation unit are controlled in accordance with an operation on the operation unit, the measurement signal and the control signal are given to the device under measurement, and the processing result of the signal analysis unit is displayed on the display unit In the device measuring apparatus for portable terminal which has the control part (33) to display on,
In the control unit,
Control command storage means (110a) for storing control commands defined for the device under measurement; control sequence storage means (110c) for storing a control sequence indicating the execution order of the control commands; Control for causing the control commands stored in the control command storage means to be selected and specified in an arbitrary order on the screen of the display unit, and storing the selected and specified control commands as one control sequence in the control sequence storage means Control sequence creation means (110) having sequence edit registration means (110d) is provided,
The control sequence stored in the control sequence storage means is displayed on the display unit so that it can be selected and designated by operation of the operation unit, and the control sequence designated by the operation unit is executed.

Moreover, the device measuring apparatus for portable terminals of Claim 2 of this invention is the device measuring apparatus for portable terminals of Claim 1,
The control sequence creation means includes a trigger generation command for causing the measurement signal generation unit or the signal analysis unit to output a trigger signal at an arbitrary timing when a control sequence for the device under measurement is being executed. It is formed so that it can be included in a control sequence.

A mobile terminal device measurement apparatus according to claim 3 of the present invention is the mobile terminal device measurement apparatus according to claim 1 or 2,
The control sequence editing / registering means is configured to arbitrarily set an execution interval between the control commands executed in the control sequence.

Moreover, the device measuring apparatus for portable terminals of Claim 4 of this invention is the device measuring apparatus for portable terminals in any one of Claims 1-3,
The control sequence edit registration means includes:
A control command display field in which a control command defined for the device under test can be edited, a name of a desired control sequence, and a plurality of the control commands executed for the desired control sequence are arranged in a tree form and in the order of execution. Display the control sequence tree display field displayed side by side on the same screen of the display unit,
By the operation from the operation unit, the control command displayed in the control command display field can be registered in the control sequence tree display field,
When a control sequence displayed in the control sequence tree display column is selected and operated, the control sequence is executed on the device under measurement.

  As described above, the mobile terminal device measurement apparatus of the present invention can create a control sequence by simply selecting and specifying the control commands stored in the control command storage means in any order on the screen of the display unit. Since the control sequence can be selected and specified by operating the operation unit, even a person who does not have specialized knowledge can easily control the device under measurement.

  In addition, since the trigger generation command can be created by including it in the control sequence, the processing of the measurement signal generation unit and the signal analysis unit can be linked with the control of the device.

  In addition, if the execution interval between each control command executed in the control sequence can be set arbitrarily, the interval between control commands given to the device under test can be set arbitrarily within a series of control sequences. It is possible to perform correct control according to the specifications of the device, and it is possible to know the tolerance of the device under measurement with respect to the interval for giving the command.

  In addition, a control command display field in which the control commands defined for the device under test can be edited, and the name of the desired control sequence and a plurality of control commands executed for the desired control sequence are executed in a tree shape. The control sequence tree display column arranged in order is displayed on the same screen of the display unit, and the control command displayed in the control command display column can be registered in the control sequence tree display column by operation from the operation unit, and its control When a control sequence displayed in the sequence tree display field is selected and operated, the control sequence selected for the device under test is selected on the same screen. Any control sequence can be registered in the control sequence tree display field with an extremely simple and intuitive operation. You can create, also simply select operation by the operation unit and the control sequence, can immediately execute the control sequence.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a configuration of a mobile terminal device measuring apparatus 20 (hereinafter simply referred to as a measuring apparatus 20) to which the present invention is applied. Here, the device under measurement 1 is a multimode IC in which the signal paths of the transmission unit and the reception unit are independent, and a high-frequency signal input terminal 1a, a baseband signal output terminal 1b, a baseband signal input terminal 1c, and a high-frequency signal output. It is assumed that a terminal 1d, a control signal input terminal 1e, and a power supply terminal 1f are provided.

  The measurement apparatus 20 includes a measurement signal generation unit 21, a control signal generation unit 22, a signal analysis unit 23, a power supply unit 24, an external interface 25, an operation unit 31, a display unit 32, and a control unit 33. It is an integral type housed in one housing (not shown).

  The measurement signal generator 21 generates a high frequency (radio frequency) measurement signal Srf to be supplied to the device under test 1 for a portable terminal, and outputs the measurement signal Srf from the output terminal 20a. And a baseband signal generator 21b that generates a signal Sbb and outputs it from the output terminal 20b. Here, one output terminal 20 a is connected to the high-frequency signal input terminal 1 a of the device under measurement 1, and the other output terminal 20 b is connected to the baseband signal input terminal 1 c of the device under measurement 1.

  The control unit 33 controls the level, frequency, modulation data and modulation method of the measurement signal Srf output from the high frequency signal generation unit 21a, and the modulation data and modulation method of the measurement signal Sbb output from the baseband signal generation unit 21b. .

  The control signal generator 22 generates a control signal to be given to the device under measurement 1, outputs it to the output terminal 20c, and inputs it to the control signal input terminal 1e of the device under measurement 1 connected to this output terminal 20c. .

  For example, the control unit 33 receives signals for controlling a local frequency or the like that determines the transmission / reception frequency of the device under test 1 (serial data including addresses and parameters, and a three-wire serial signal including a clock signal and an enable signal). Output under control.

  The signal analysis unit 23 is for performing analysis processing of the high-frequency signal Rrf and the baseband signal Rbb output from the device under measurement 1, and is output from the high-frequency signal output terminal 1d of the device under measurement 1 at a radio frequency. The baseband signal output from the baseband signal output terminal 1b of the device under test 1 and the baseband signal output terminal 1b of the device under test 1 for receiving the high-frequency signal Rrf at the input terminal 20d and performing spectrum analysis processing and demodulating the high-frequency signal for modulation analysis A baseband signal analyzing unit 23b that receives Rbb at the input terminal 20e and performs analysis processing. Each of the analysis units 23 a and 23 b is connected to the control unit 33 by a bus. Various parameters necessary for the analysis process are set by the control unit 33, and the analysis result is sent to the control unit 33.

  The power supply unit 24 generates power necessary for operating the device under measurement 1 and supplies the power to the power supply terminal 1f of the device under measurement 1 from the power output terminal 20f. The power supply unit 24 is also controlled by the control unit 33.

  The external interface 25 includes, for example, a GPIB interface 25a and an Ethernet (registered trademark) (LAN) interface 25b, which are generally used in measurement equipment, and the measurement signal generator 21 and signal analysis described above. When performing measurement that is difficult only with the built-in measurement device such as the unit 23 (for example, IM measurement that requires high-frequency signals having different frequencies at the same time), another device is connected via the external interface 25. Control is performed by the control unit 33. The external interface 25 may use USB in addition to the above.

  The operation unit 31 includes a pointing device for selecting a button displayed on the screen of the display unit 32 with a cursor, such as a number of keys, a dial and a keyboard that can be connected externally, or a mouse. The operation is detected by the unit 33.

  The display unit 32 is a display (LCD, CRT) capable of displaying an image such as a waveform, and may be an externally connectable one in addition to the one provided integrally with the housing.

  The control unit 33 is configured by a computer including a ROM, a RAM, a CPU, an HDD, an interface, and the like, and according to the operation of the operation unit 32, the measurement signal generation unit 21, the control signal generation unit 22, and the signal analysis unit 23 described above. Then, the power supply unit 24 and the external interface 25 are controlled to cause the device under measurement 1 to perform measurement, and the measurement result and the like are displayed on the display unit 32.

  Here, the processing of the control unit 33 is for creating and registering an arbitrary control sequence for the device under measurement 1 in addition to the normal measurement mode in which the measurement is performed by setting parameters necessary for the operation of each unit described above. A control sequence creation mode, a measurement sequence creation mode for creating and registering a measurement sequence for performing a specific measurement by performing a series of control for each unit described above including this control sequence, and an external interface 25. And an external device control panel creation mode for easily performing control operations of devices (externally connected devices) connected via the control unit 33. In FIG. Measurement control means 100, control sequence creation means 110, measurement sequence creation means 120, and external device control panel creation means 130 It is shown in an lock of.

  The measurement control means 100 is provided not only with a function for individually setting parameters of each part but also with a tutorial function for guiding so that anyone can easily set parameters necessary for each measurement item.

  The tutorial function can be activated by performing a predetermined operation using the operation unit 31. For example, an activation screen as shown in FIG. 2 can be displayed and the setting process can be performed in order.

  In this embodiment, a case where each process of the control unit 33 is realized by application software using Windows (registered trademark) of Microsoft (registered trademark) as basic software (OS) will be described. (Trademark), UNIX (registered trademark), Linux (registered trademark), TRON (registered trademark), and other applications.

  When the “System” button 200 is selected (for example, clicked with a mouse cursor) on the screen of FIG. 2, a system setting screen as shown in FIG. 3 is displayed.

  In this system screen, a window 210 for selecting a communication method such as WCDMA and GSM, a window 211 for selecting analog / digital of the baseband interface of the device under measurement, a window 212 for selecting measurement items (Uplink Power...), A window 213 for selecting the format of the modulation signal of the measurement signal Srf output by the high-frequency signal generator 21a, a window 214 for selecting the format of the measurement signal Sbb output by the baseband signal generator 21b, and the power supply for the device under measurement A window 215 or the like for selecting on / off is displayed.

  Further, when the “New” button 216 at the position of “3-Wire Control Data” is clicked on the screen of FIG. 3, the control sequence creating unit 110 is activated.

  As shown in FIG. 4, the control sequence creating means 110 has a control command (for example, serial data comprising address data and setting data for determining the state of the part indicated by the address) defined uniquely for each device 1 to be measured. Code) and a control command name thereof are stored in association with each other, and a control command storage unit 110a for storing an associated control command name and a control command registration unit 110b for registering an arbitrary control command in the control command storage unit 110a, and one or a plurality of control commands. Control sequence name of the control sequence to be executed, control sequence storage means 110c for storing an arbitrary control sequence, and control command to be executed with an arbitrary control sequence name from the control command stored in the control command storage means 110a Select a command arbitrarily and save the control sequence. Is registered to 110c, it has a control sequence registered editing means 110d for causing edits to the registered control sequence, and a control signal waveform generating means 110e.

  The control command storage means 110a and the control sequence storage means 110c are detachable memory units (card type, stick type, etc.) in addition to the readable / writable nonvolatile semiconductor memory and disk type storage element in the apparatus. May be.

  When the control sequence creation unit 110 is activated, a screen as shown in FIG. 5 is displayed, for example. A window 220 on the right side of the screen in FIG. 5 is a control command display field, and each control command (serial code of 0 and 1) stored in the control command storage unit 110a corresponds to a command name such as “RST1”. An editing operation such as addition or change can be arbitrarily performed on the screen by the operation of the operation unit 31.

  The left window 221 is a control sequence tree display field, and an arbitrary control sequence name (folder icon) such as “VCOInit” and “TXFreqSet” and a control command name executed with the sequence name, for example, “RST1”. , “TxSHDN1”, “TxDLE1”, and “TxFreqInit1” are displayed in a tree-like manner and arranged in order of execution so that they can be edited.

  A central window 222 in FIG. 5 is a sequence detail column. In addition to the control command name and pattern included in the selected control sequence among the control sequences displayed in the left window 221, the control command execution interval is displayed. “Time” is displayed. This execution interval represents the time from when one control command is executed until the next control command is executed, and can be arbitrarily set by operating the operation unit 31. Note that, here, the execution interval is indicated by time in μS units, but may be indicated by the number of system clocks.

  In this screen, the control command editing operation for the right window 220, the control sequence name input operation for the left window 221 and the control command registration operation for the sequence name, and the execution interval input operation for the center window 222, etc. As described above, it can be arbitrarily performed by operating a mouse or a key.

  In addition, by selecting one of the tabs 223 to 226 of “Control 1”, “Control 2”,..., “Control 4”, each control terminal is provided for each control terminal. The control sequence can be registered.

  When the “All List” tab 227 is clicked in FIG. 5, the contents (control sequence) of the left window 221 are displayed in a list as shown in FIG. 6, for example.

  When the “All Pattern” tab 228 is clicked, the contents (control commands) of the right window 220 are displayed in a list as shown in FIG. 7, for example.

  After creating the control sequence as described above, when the created control sequence is selected and the “Convert” button 229 at the top is operated, not only the data of the control command but also the data are measured. The waveform data of the clock signal and the enable signal necessary for serial transfer are created by the control signal waveform generation means 110e and registered in the control sequence storage means 110c.

  In this control sequence, as described in the lowermost part of the left window 221 in FIG. 5, other control devices are inspected while the control sequence for the device under measurement is being performed or at the end timing. A trigger generation command “TRIG” for generating a trigger signal can be registered.

  In the control sequence including the trigger generation command, the registered control commands are executed in order. When the order of the trigger generation command is reached, the trigger signal is sent from the control signal generator 22 according to the contents set for the trigger generation command. generate.

  In response to this trigger signal, each measuring device generates, for example, a measurement signal or starts an analysis process. As described above, since the trigger signal can be output in conjunction with the control command, various measurements can be efficiently and automatically started.

  Note that the selected control sequence is executed for the device under measurement by performing a predetermined selection operation (for example, a double-click operation) on the control sequence name displayed in the left window 221 on the screen of FIG. Can be done.

  When the “Exit” button 230 is clicked on the screen shown in FIG. 5 after the above-described control sequence creation processing is completed, the system setting screen shown in FIG. 3 is displayed again, and a desired control sequence is set in the window 217. When the “Ok” button 218 is clicked after the parameters are set, the tutorial screen of FIG. 2 is restored.

  When the “Trace” button 201 is clicked, a window 231 indicating the screen layout and a plurality of windows 232 to 235 for setting the display contents are displayed as shown in FIG. Is selected and designated, and the “Ok” button 236 is operated, the screen returns to the tutorial screen.

  When the “Trigger” button 202 is clicked on the tutorial screen, a screen for selecting a trigger transmission source, a trigger reception destination, a trigger type, a delay time, an edge, etc. is displayed as shown in FIG. The When the “Ok” button 238 is clicked on this screen, the screen returns to the tutorial screen of FIG. The screen in FIG. 9 is a screen when the trigger signal is not output from the control signal generator 22, and when the trigger signal is set to be generated from the control signal generator 22 as described above, the screen is also displayed. Is displayed.

  Then, when the “Parameter” button 203 is clicked on the tutorial screen, a screen for setting the frequency of the input signal to the device under test is displayed as shown in FIG. 10, and if the “Advanced” button 240 is clicked on this screen, 11, a more detailed parameter setting screen is displayed. When the “Common” tab 241 is switched to the “Measurement” tab 242 in FIG. 10, a parameter setting screen as shown in FIG. 12 is displayed.

  When the “Ok” button 243 is clicked in FIG. 10 to FIG. 12, the tutorial screen of FIG. 2 is returned, and if the “Set” button 204 is clicked on this tutorial screen, each setting information set so far is required. Each point is set and measurement preparation is completed.

  Finally, when the “Operation” button 205 is clicked, a screen for setting the power on / off of the device under measurement, the selection setting of the control sequence, the pattern format of the baseband signal, etc. is displayed as shown in FIG. When the measurement is started by performing the operation and the “Close” button 249 is clicked, a measurement screen as shown in FIG. 14 is displayed, for example.

In the example of the measurement screen in FIG. 14, parameters and measurement results in the modulation analysis result (Modulation Analysis) are numerically displayed in the upper left column of the four-divided screen, and the modulation analysis result of the modulation analysis result is displayed in the upper right column. Error (RMS
EVM) is displayed, the spectrum of the transmission output (channel power) is displayed in the lower left column, and the waveforms of the demodulated baseband signals I and Q are displayed in the lower right column.

  On the other hand, as shown in FIG. 15, the measurement sequence creation means 120 includes one or a plurality of measurement command storage means 120a that stores in advance commands (GPIB commands) necessary for controlling each of the measurement devices described above. From the measurement sequence storage means 120b for storing the sequence name of the measurement sequence realized by the measurement command and the arbitrary measurement sequence in association with each other, from the measurement command stored in the measurement command storage means 120a, any A measurement sequence registration editing unit 120c for arbitrarily selecting a measurement command to be executed with a measurement sequence name, registering the measurement command in the measurement sequence storage unit 120b, and editing the registered control sequence; Yes.

  The measurement sequence creation means 120 is activated by a predetermined operation on the operation unit 31 including an operation for newly registering a measurement item in the above-described tutorial, and displays a screen as shown in FIG. 16, for example. In the right window 250 of FIG. 16, commands to be executed for each built-in device and each device connected via the external interface 25 are displayed in order of execution for one measurement sequence name.

  This command corresponds to the name of the control target device (“Type” column) such as “DC (power supply)” and “SG (high frequency signal generator)”, the command name arbitrarily created by the tester (Name column), and the command name. GPIB command (Command column).

  In this measurement sequence, the process of giving a control command to the device under measurement 1 (for example, “Initial”) is realized by the transfer command “SEND DUT LIST1”.

  In the upper left window 251, the names of control target devices such as “SG” and “SA” and GPIB commands such as “FREQ 1900 MHz” and “LEVEL −10 dBm” that can be used for the device are registered. A command arbitrarily selected from the window 251 can be inserted into the right window 250 to create a measurement sequence.

  A series of measurement sequences created in the right window 250 in this manner is clicked on the “Save file” button 253 and a measurement sequence name is arbitrarily set, so that a measurement sequence file is stored in the measurement sequence storage unit 120b. You can register. Further, the registered measurement sequence file can be displayed, and an arbitrary one can be registered as a part constituting another measurement sequence like the window 252 at the lower left.

  Furthermore, when the “Device Tester” tab 254 is switched to the “External Equipment” tab 255, the measurement command for the external device “6612c” (blank in the figure) is displayed in the left window 251 as shown in FIG. Any of these commands can be added to the measurement sequence of the right window 250.

  The commands (GPIB commands) constituting the above measurement sequence are classified and registered in advance for each device to be controlled, and an arbitrary measurement sequence for the device under measurement can be selected by simply selecting and operating them. Anyone can easily create it without being aware of the programming language. Note that the commands used for the measurement sequence are registered in advance for each built-in device. In addition, for externally connected devices, a list can be created on this screen, and it is also possible to register in a file format from the outside.

  In addition, the measurement apparatus 20 according to the embodiment includes an external device control panel creating unit 130 for easily controlling a device connected to the outside from the device measurement device side.

  The external device control panel creating unit 130 is activated when a predetermined operation is performed on the operation unit 31 and causes the display unit 32 to display a screen shown on the left side of FIG.

  In the upper column 260 on the left side of the screen, the name of an externally connected device such as “MG3681A” is input and can be selected.

  In the lower column, a plurality of command buttons 261 to 265 that can be executed for the external device and parameter windows 266 to 268 are displayed.

  In this example, a command “Initial” button 261 for initializing the signal generator MG3681A, “Send” buttons 262 to 263 for setting a frequency, an output level, and an offset, and “RF ON” for outputting a signal. A control panel including a button 264 and parameter windows 266 to 268 of “freq MHz”, “Level dBm”, and “Offset dB” is displayed.

  When the “Open” button 269 of the left control panel is operated, panel definition information for creating a control panel is displayed as shown in the right part of FIG.

That is, the definition sentence at the beginning,
No, ButtonName, ItemName, Control, Digit, Unit, Lower, Upper, Command
Is displayed, and currently set panel information is displayed in the lower row.

  Here, “No” in the definition statement is the button number (added 1 from the top of the screen), “ButtonName” is the name assigned to the button, “ItemName” is the function name, and “Control” is the edit box (Edit) Determine the parts of the screen, such as the spin box (Spin). "Digit" defines the number of digits from the decimal point to the following. For example, in the case of 120.00 dBm and 3 digits after the decimal point and 2 digits after the decimal point, “3.2” is defined. “Unit” indicates a unit, “Lower” indicates a lower limit value when a numerical value is input, and “Upper” indicates an upper limit value when a numerical value is input. “Command” defines a GPIB command.

  The external device operation panel creation means 130 automatically generates a control panel such as the left part based on the panel definition information on the right part of FIG. 18, and corresponds to the button when the button on the control panel is operated. A GPIB command is transferred to an externally connected device via the external interface 25 so that the device can be controlled.

  That is, if the GPIB command is a known device, the panel information as shown in FIG. 17 can be created according to the above definition sentence, and the left control panel is automatically set based on the created panel information. Is generated.

  Therefore, a measuring instrument that has once created a control panel can be easily remotely controlled by simply operating the control panel without being aware of the GPIB command.

  More specifically, the panel definition information is converted into an electronic file for each device name and stored in a predetermined location such as an HDD of the control unit 33. Further, when the panel definition information is converted to an electronic file, the file name includes the device name. Then, the external device control panel creation means refers to the file name of the electronic file stored in the predetermined location when the screen shown on the left side of FIG. 18 is displayed on the display unit 32 as described above. The file name (or part thereof) is displayed as the device name in the upper column 260 on the left side of the screen. If there are a plurality of stored electronic files, the device name is displayed so that the device name can be selected by the pull-down menu function. When the device name is selected by operating the operation unit 31, panel definition information corresponding to the device name is displayed. Generates a control panel.

  The control sequence creation process, the measurement sequence creation process, and the external device control panel creation process described above can be started at an arbitrary timing (even during measurement) by a predetermined operation on the operation unit 31.

  Furthermore, control commands that can be set for a plurality of devices to be measured, GPIB commands for each measuring device, and the like can be assigned to the plurality of function keys 300 to 307 displayed on the right side of the measurement screen illustrated in FIG. It is like that. In addition, a power setting operation unit 310, a device control operation unit 320, a measurement device control operation unit 330, and the like are displayed in the lower part of the measurement screen, and keys such as “Menu” are displayed in the lowermost part of the measurement screen. . The transition to each of the creation processes described above can be performed by operating these keys.

  As described above, the measuring apparatus 20 according to the embodiment can create a control sequence simply by selecting and specifying the control commands stored in the control command storage unit 110a on the screen of the display unit 32 in any order. Since the control sequence can be selected and specified by operating the operation unit 31, even a person who does not have specialized knowledge can easily control the device under measurement.

  In addition, since the trigger generation command can be created by including it in the control sequence, the processing of the measurement signal generator 21 and the signal analyzer 23 can be linked in association with the control of the device under measurement.

  In addition, since the execution interval between each control command executed in the control sequence can be arbitrarily set, the interval of the control commands given to the device under test can be arbitrarily set within the series of control sequences. It is possible to perform correct control according to the specifications of the device, and it is possible to know the tolerance of the device under test with respect to the interval for giving the command.

  In addition, a control command display field in which the control commands defined for the device under test can be edited, and the name of the desired control sequence and a plurality of control commands executed for the desired control sequence are executed in a tree shape. The control sequence tree display column arranged in order is displayed on the same screen of the display unit, and the control command displayed in the control command display column can be registered in the control sequence tree display column by operation from the operation unit, and its control When a control sequence displayed in the sequence tree display field is selected and operated, the control sequence selected for the device under test is selected on the same screen. Any control sequence can be registered in the control sequence tree display field with an extremely simple and intuitive operation. You can create, also simply select operation by the operation unit and the control sequence, can immediately execute the control sequence.

The figure which shows the whole structure of embodiment of this invention. The figure which shows the example of a screen display for demonstrating operation | movement of the principal part of embodiment. Figure showing an example of the system setting screen The figure which shows the structure of the principal part of embodiment. Diagram showing an example of the control sequence creation screen Diagram showing an example of the control sequence creation screen Diagram showing an example of the control sequence creation screen Diagram showing an example of the layout setting screen Diagram showing an example of the trigger setting screen Diagram showing an example of the parameter setting screen Diagram showing an example of the parameter setting screen Diagram showing an example of the parameter setting screen Figure showing an example of the operation screen Diagram showing an example of the measurement status screen The figure which shows the structure of the principal part of embodiment. Figure showing an example of the measurement sequence creation screen Figure showing an example of the measurement sequence creation screen The figure which shows an example of the external device operation panel creation screen The figure which shows the structure of the device for portable terminals

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Device to be measured, 20 ... Device measuring device for portable terminals, 21 ... Signal generator for measurement, 21a ... High frequency signal generator, 21b ... Baseband signal generator, 22 ... Control signal generator , 23... Signal analysis section, 23 a... High frequency signal analysis section, 23 b... Baseband signal analysis section, 24... Power supply section, 25... External interface, 31 ... Operation section, 32 display section, 33. Control unit 100... Measurement control means 110... Control sequence creation means 110 a. Control command storage means 110 b. Control command registration means 110 c. Control sequence storage means 110 d. 110e... Control signal waveform generation means, 120... Measurement sequence creation means, 120a... Measurement command storage means, 120b. Be stored means, 120c ...... measurement sequence registration editing means, 130 ...... external device control panel creating means

Claims (4)

A measurement signal generator (21) for generating a measurement signal to be given to a device under test for a portable terminal;
A control signal generator (22) for generating a control signal to be given to the device under measurement;
A signal analysis unit (23) for performing an analysis process of an output signal of the device under measurement;
An operation unit (31);
A display unit (32);
The measurement signal generation unit and the control signal generation unit are controlled in accordance with an operation on the operation unit, the measurement signal and the control signal are given to the device under measurement, and the processing result of the signal analysis unit is displayed on the display unit In the device measuring apparatus for portable terminal which has the control part (33) to display on,
In the control unit,
Control command storage means (110a) for storing control commands defined for the device under measurement; control sequence storage means (110c) for storing a control sequence indicating the execution order of the control commands; Control for causing the control commands stored in the control command storage means to be selected and specified in an arbitrary order on the screen of the display unit, and storing the selected and specified control commands as one control sequence in the control sequence storage means Control sequence creation means (110) having sequence edit registration means (110d) is provided,
For a portable terminal, wherein the control sequence stored in the control sequence storage means is displayed on the display unit so that it can be selected and specified by operation of the operation unit, and the control sequence specified by the operation unit is executed. Device measuring device.   The control sequence creation means includes a trigger generation command for causing the measurement signal generation unit or the signal analysis unit to output a trigger signal at an arbitrary timing when a control sequence for the device under measurement is being executed. The device measuring apparatus for a portable terminal according to claim 1, wherein the device measuring apparatus is configured to be included in a control sequence.   The portable terminal according to claim 1 or 2, wherein the control sequence edit registration unit is configured to arbitrarily set an execution interval between the control commands executed in the control sequence. Device measuring device. The control sequence edit registration means includes:
A control command display field in which a control command defined for the device under test can be edited, a name of a desired control sequence, and a plurality of the control commands executed for the desired control sequence are arranged in a tree form and in the order of execution. Display the control sequence tree display columns arranged on the same screen of the display unit,
By the operation from the operation unit, the control command displayed in the control command display field can be registered in the control sequence tree display field,
The mobile phone according to any one of claims 1 to 3, wherein when a control sequence displayed in the control sequence tree display field is selected and operated, the control sequence is executed for a device under measurement. Device measurement device for terminals.

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