JP2015129648A - Testing system and testing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently and reliably perform a cable connection work when a plurality of cables for connecting a testing device and a device to be tested are connected.SOLUTION: The testing system includes a testing device 12 for performing a test for a device 110 to be tested and a plurality of test cables 162 for connecting a device to be tested with the testing device. The system determines whether a connection order of the testing cables is right, indicates that the connection order of the testing cables is right when the connection order of the testing cables is right, and performs the electric connection confirmation of the testing cables by using a scalar network analyzer or a digital multi-meter with reference to a cable related information table for storing identification information on the testing cables used in the testing, connection order information by which the testing cables are to be connected, and a position detailed map of an opposite-side connector to be connected with the testing cables in association based on the identification information read from a reading device.

Description

  The present invention relates to a test system and a test method for testing a device under test.

For example, Patent Document 1 discloses a test system (test apparatus) that can easily check the test implementation status.
Here, a conventional test system will be described with reference to FIG.
FIG. 12 is a diagram illustrating an example of a configuration of a conventional test system.
As shown in FIG. 12, the conventional test system 100 is configured by connecting a test apparatus 10 and a device under test 110 via a plurality of test cables 160.
The device under test 110 is an object of a test executed by the test apparatus 10.
The test apparatus 10 includes a computer 2, measuring instruments 120-1 to 120-N (N is an integer equal to or greater than 1. However, N is not always the same number), a dedicated tester 130, and a switching unit 140. ing.

Hereinafter, in the case where any one of a plurality of components such as the measuring instruments 120-1 to 120-N is not specified, the measuring instrument 120-1 may be simply abbreviated.
Also, any two or more of the devices constituting the test system 100 shown in FIG. 12 can be appropriately integrated.
In addition, a plurality of functions realized in one device may be realized in separate devices, or may be realized in any device other than the device shown in FIG. Good.

The computer 2 includes a controller 20 and a device under test controller 22 connected via an inter-PC control line, and executes a predetermined test.
The computer 2 stores test software, and when the test is performed, the device under test 110 and the test apparatus 10 are connected to a test cable 160 (power cable, RF cable, communication cable, etc.). Connected with.
There are a plurality of types of test cables 160 used for the test, and the test cable 160 is used exclusively for each device under test 110.

The controller 20 is a computer, for example, and controls the switching unit 140 and the measuring device 120.
Specifically, the controller 20 transmits a switching signal to the switching unit 140 in order to switch the measurement path so that the measurement signal is input to the measuring device 120 used according to the test content.
In addition, the controller 20 displays a connection diagram (described later with reference to FIG. 13) indicating how a plurality of test cables 160 that connect the test apparatus 10 and the device under test 110 should be connected. .
The connection diagram may be displayed not by the controller 20 but by the device under test controller 22.

The device under test controller 22 is, for example, a computer and causes the device under test 110 to input a signal indicating a measurement condition (measurement condition signal).
The device under test 110 that has received the measurement condition signal executes a predetermined test, and outputs a test signal as a test result to the measuring device 120 or the dedicated tester 130 via the switching unit 140.
The measuring device 120 is a general-purpose measuring device and is used in a test executed by the computer 2 and receives a test signal output from the device under test 110 via the switching unit 140 to perform a predetermined measurement.
The dedicated tester 130 is a tester used exclusively for each device under test 110 (and each test item), and receives a test signal output from the device under test 110 via the switching unit 140. Perform a predetermined measurement.

The switching unit 140 switches the measurement path between the device under test 110, the measuring device 120, and the dedicated testing device 130 in accordance with a switching signal input from the controller 20 via the switching control line.
For example, when the test signal from the device under test 110 is to be measured by the measuring device 120-1, the switching unit 140 electrically connects the cable 160 to which the test signal is transmitted and the measuring device 120-1. To switch routes.
The switching unit 140 includes a measuring device connection unit 142 that connects the measuring device 120 and the device under test 110, and a dedicated test device connection unit 144 that connects the dedicated test device 130 and the device under test 110.

One of the measuring instrument connecting portions 142 is connected to the measuring instrument 120. Further, the measuring instrument connection section 142 has a connector for connecting a test cable 160 used for communication of a test signal with the device under test 110 on the other side.
One of the dedicated tester connection portions 144 is connected to the dedicated tester 130, and the other is a connector for connecting a test cable 160 used for communication of a test signal with the device under test 110. have.
Hereinafter, the measuring instrument connection part 142 and the dedicated tester connection part 144 may be collectively referred to as “the measuring instrument connection part 142 or the like”.

FIG. 13 is a diagram illustrating a connection diagram displayed by the controller 20 and a device under test 110 to which a cable is connected corresponding to the connection diagram. FIG. 13A illustrates the connection diagram. ) Shows the device under test 110 to which a cable is connected.
As shown in FIG. 13A, one end of the cable W1 is connected to the connectors P1, P2, and P3 of the device under test 110, and the other end is connected to the connectors J1 and J2 of the measuring instrument connecting portion 142. Is done.
Also, one end of the cable W2 is connected to the connector P20 of the device under test 110, and the other end is connected to the connector J10 of the dedicated tester connection unit 144.
The operator confirms the connection diagram displayed on the controller 20 to connect the cable 160 to the device under test 110 and the measuring device connection portion 142 as shown in FIG. 13B.

In the conventional test system 100 described above, an operator prepares a plurality of test cables 160 to be used in the test before starting the test, and looks at the connection state diagram (see FIG. 13) displayed on the controller 20. The operation of connecting each test cable 160 to the device under test 110 and the measuring device connection 142 is performed. However, since the cable connection state diagram displayed on the controller 20 is a connection display in a state where the connector is inserted, it is not possible to know what shape the connector of the connection partner is and where it is located. It took time to search.
In addition, when connecting a plurality of test cables 160, there is a problem that it is not possible to know the connection status of which cable is currently connected.

  Also, check whether the test cable 160 side connector is securely fitted to the other connector such as the device under test 110 and the measuring device connection portion 142, and the electrical connection state is good. I could not.

JP 2010-281707 A

  The present invention has been made in view of such a situation, and a test capable of efficiently and reliably performing cable connection work when connecting a plurality of cables connecting a test apparatus and a device under test. The purpose is to provide a system.

  The test system according to the present invention includes a test apparatus for testing a device under test, and a plurality of test cables for connecting the device under test and the test apparatus. And a storage medium storing identification information for identifying the plurality of test cables, and a reading device that reads the identification information from the storage medium attached to each of the plurality of test cables. A scalar network analyzer or digital multimeter for confirming the electrical connection of the test cable, and the test apparatus is connected to the identification information of the test cable used in the test and the test cable. A cable for storing the connection order information to be associated with the detailed position diagram of the mating connector to which the test cable is to be connected When the connection order of the test cables is determined by referring to the cable related information table based on the related information table and the identification information read by the reader, and the connection order of the test cables is correct The display showing that the connection order of the test cables is correct, while confirming the electrical connection of the test cables using the scalar network analyzer or the digital multimeter, the electrical connection of the test cables is confirmed. If it is correct, a display indicating that the electrical connection of the test cable is correct is displayed, while a display indicating the test cable in the next connection order is displayed.

  In the test system described above, the test apparatus includes display means for displaying a connection state diagram of the test cable and the mating connector, or display means for displaying a detailed position diagram of the mating connector of the test cable. And when the connection order of the test cables is correct, the connection state diagram or the detailed position diagram displays that the connection order of the test cables is correct, while the scalar network analyzer or the digital Use a multimeter to check the electrical connection of the test cable. If the electrical connection of the test cable is correct, check that the electrical connection of the test cable is correct in the connection state diagram or the detailed position diagram. The display indicating the test cable in the next connection order is performed.

  Further, the test method of the present invention is used in the test in a test system having a test apparatus for testing the device under test and a plurality of test cables connecting the device under test and the test apparatus. Related information table for storing the identification information of the test cable to be connected, the connection order information to which the test cable is to be connected, and the detailed position diagram of the mating connector to which the test cable is to be connected Then, referring to the cable related information table based on the identification information read by the reader, it is determined whether the test cable connection order is correct. If the test cable connection order is correct, the test is performed. While displaying that the cable connection order is correct, use a scalar network analyzer or digital multimeter to test the cable. If the electrical connection of the test cable is correct, a display indicating that the electrical connection of the test cable is correct is displayed, while a display indicating the test cable of the next connection order is displayed. It is characterized by performing.

  ADVANTAGE OF THE INVENTION According to this invention, the cable connection operation | work at the time of connecting the some cable which connects a test apparatus and a to-be-tested device can be performed efficiently and reliably.

It is a figure which shows an example of a structure of the test system which concerns on Embodiment 1 of this invention. It is a figure which shows an example of the hardware constitutions of the controller in the test system which concerns on Embodiment 1 of this invention. It is a figure which shows an example of the cable for a test in the test system which concerns on Embodiment 1 of this invention. It is a figure which shows an example of the cable connection preparation program which operate | moves in the controller in the test system which concerns on Embodiment 1 of this invention. 4 is a diagram showing a cable-related information table for each device under test stored in a cable-related information storage unit 300. FIG. It is a figure which shows the cable relevant information table for every test item memorize | stored in the cable relevant information storage part. It is an example of a screen which displays the connection figure of a use cable, and a connection state figure. It is an example of a screen in the case of changing a cable color on the screen of FIG. 7 or displaying a detailed connector position diagram by the processing of the connection order confirmation unit 330. It is a flowchart which shows the cable connection confirmation process for a test performed in the test system which concerns on Embodiment 1 of this invention. It is a flowchart which shows the electrical connection check process performed in step S111 of FIG. It is a flowchart which shows the electrical connection check process performed in step S111 of FIG. It is a figure which shows an example of a structure of the conventional test system. FIG. 2 is a connection diagram displayed by a controller 20 and a diagram showing a device under test 110 to which a cable is connected in accordance with the connection diagram.

<Embodiment 1>
[Control configuration of test system]
Hereinafter, the test system according to Embodiment 1 of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a diagram illustrating an example of a configuration of a test system according to Embodiment 1 of the present invention.
In addition, the same code | symbol is attached | subjected to the substantially same part as the component of the conventional test system 100 shown in FIG. 12 among the test systems 1 concerning Embodiment 1 shown in FIG.

As shown in FIG. 1, the test system 1 according to the first embodiment of the present invention is configured by connecting a test apparatus 12 and a device under test 110 via a plurality of test cables 162.
The device under test 110 is an object of a test executed by the test apparatus 10.
The test apparatus 12 includes a computer 3, measuring instruments 150-1 to 150-N (N is an integer equal to or greater than 1. However, N is not always the same number), a dedicated tester 130, and a switching unit 140. ing.
Further, a tag reader 180 that is a reading device that reads cable identification information stored in an RFID tag 164 that is an example of a storage medium attached to the test cable 162 is provided in the vicinity of the switching unit 140.

Hereinafter, in the case where any one of a plurality of components such as measuring instruments 150-1 to 150-N is not specified, it may be simply abbreviated as measuring instrument 150 or the like.
Also, any two or more of the devices constituting the test system 1 shown in FIG. 1 can be appropriately integrated.
In addition, a plurality of functions realized in one device may be realized in separate devices, or may be realized in any device other than the device shown in FIG. Good.

The computer 3 is configured by connecting a controller 24 and a controller under test 22 via an inter-PC control line, and executes a predetermined test.
The computer 3 stores test software. When the test is performed, the device under test 110 and the test apparatus 12 are connected to the test cable 162 (power cable, RF cable, communication cable, etc.). Connected with.
There are a plurality of types of test cables 162 used for the test, and a plurality of different types of test cables 162 are used for each test device 110 and for each test item.

The controller 24 is, for example, a computer, and controls the switching unit 140 and the measuring device 150.
Specifically, the controller 24 transmits a switching signal to the switching unit 140 in order to switch the measurement path so that the measurement signal is input to the measuring device 150 used according to the test content.
Further, the controller 24 displays a connection diagram (to be described later with reference to FIG. 7) indicating how a plurality of test cables 162 that connect the test apparatus 12 and the device under test 110 should be connected. .
The connection diagram may be displayed not by the controller 24 but by the device under test controller 22.

The device under test controller 22 is, for example, a computer and causes the device under test 110 to input a signal indicating a measurement condition (measurement condition signal).
The device under test 110 that has received the measurement condition signal executes a predetermined test, and outputs a test signal as a test result to the measuring device 150 or the dedicated tester 130 via the switching unit 140.
The measuring device 150 is a general-purpose measuring device and is used in a test executed by the computer 3. The measuring device 150 receives a test signal output from the device under test 110 via the switching unit 140 and performs a predetermined measurement. The plurality of measuring instruments 150 include a scalar network analyzer and a digital multimeter.
The dedicated tester 130 is a tester used exclusively for each device under test 110 (and each test item), and receives a test signal output from the device under test 110 via the switching unit 140. Perform a predetermined measurement.

The switching unit 140 switches measurement paths between the device under test 110, the measuring device 150, and the dedicated testing device 130 in accordance with a switching signal input from the controller 24 via the switching control line.
For example, when the test signal from the device under test 110 is to be measured by the measuring device 150-1, the switching unit 140 electrically connects the test cable 162 to which the test signal is transmitted and the measuring device 150-1. Switch the route so that it is connected to.
In addition, the switching unit 140 includes a measuring device connection unit 142 that connects the measuring device 150 and the device under test 110, and a dedicated test device connection unit 144 that connects the dedicated test device 130 and the device under test 110.

One of the measuring instrument connection portions 142 is connected to the measuring instrument 150. Further, the measuring instrument connecting section 142 has a connector for connecting a test cable 162 used for communication of a test signal with the device under test 110 on the other side.
One of the dedicated tester connection portions 144 is connected to the dedicated tester 130, and the other is a connector for connecting a test cable 162 used for communication of a test signal with the device under test 110. have.
Hereinafter, the measuring instrument connection part 142 and the dedicated tester connection part 144 may be collectively referred to as “the measuring instrument connection part 142 or the like”.

[Hardware configuration of controller and test cable]
The hardware configuration of the controller 24 and the test cable 162 will be described with reference to FIGS.
FIG. 2 is a diagram illustrating an example of a hardware configuration of the controller (and the controller under test 22) in the test system according to the first embodiment of the present invention. FIG. 3 is a diagram illustrating an example of a test cable in the test system according to Embodiment 1 of the present invention.

As shown in FIG. 2, the controller 24 includes a main body 250 including a CPU (Central Processing Unit) 252 and a memory 254, an input / output device 256 including a keyboard and a display device, and a communication device that communicates with other devices. 258, and a recording device 260 that records and reproduces data with respect to the recording medium 262, such as a CD device and an HDD device.
That is, the controller 24 has a hardware component as a computer capable of information processing and communication with other devices.

As shown in FIG. 3, an RFID tag 164 is attached to the test cable 162.
The RFID tag 164 is a RFID (Radio Frequency Identification) type storage medium, and stores cable identification information for identifying each test cable 162. The cable identification information of the test cable 162 can be, for example, W1 or W2 shown in FIG.

Between the RFID tag 164 and the tag reader 180 described above, the tag reader 180 transmits a radio wave signal to the RFID tag 164, and in response to this, the RFID tag 164 rectifies the radio wave from the tag reader 180. Power is supplied.
Further, the tag reader 180 transmits inquiry data indicating that the cable identification information of the test cable 162 is transmitted to the RFID tag 164, and the RFID tag 164 receives the inquiry data in response to the inquiry. Is transmitted to the tag reader 180.
As a result, the tag reader 180 reads the cable identification information of the test cable 162 from the RFID tag 164. Further, the tag reader 180 transmits the read cable identification information of the test cable 162 to the controller 24.

[Software configuration that operates in the controller]
A software configuration that operates in the controller 24 described above will be described with reference to FIG.
FIG. 4 is a diagram illustrating an example of a cable connection preparation program that operates in the controller in the test system according to the first embodiment of the present invention.
As shown in FIG. 4, the cable connection preparation program 30 includes a cable related information storage unit 300, a test item setting unit 302, a connection diagram display unit 304, a necessary cable determination unit 310, a necessary cable display unit 312, and a cable identification information receiving unit. 320, connection order confirmation unit 330, connection order confirmation display unit 332, measurement information reception unit 342, electrical connection quality determination unit 344, electrical connection quality display unit 346, cable connection completion determination unit 360, and cable connection completion display unit 362.

The cable connection preparation program 30 performs a test cable connection confirmation process for confirming whether or not a test cable necessary for a predetermined test has been prepared by the above configuration.
For example, the cable connection preparation program 30 is supplied to the controller 24 via the recording medium 262, loaded into the memory 254, and the hardware resources of the controller 24 are specified on the OS installed in the controller 24. It is executed using.
In the present embodiment, the controller 24, which is a computer, executes the cable connection preparation program 30, but may be realized by configuring the function of the cable connection preparation program 30 with hardware.

In the cable connection preparation program 30, the cable related information storage unit 300 stores information shown in the tables shown in FIGS.
FIG. 5 is a diagram showing a cable-related information table for each device under test stored in the cable-related information storage unit 300.
As shown in FIG. 5, in the cable-related information table 410 for each device under test, for each device under test 110, the test items executed for the device under test and the cable of the test cable 162 used for each test item. Identification information is associated.

For example, FIG. 5A shows that test items A1 to A3 are performed for the device under test A.
5A shows that test cables W1 and W2 are used in test item A1, the test device side of test cable W1 is connected to measuring instrument connection 142, and the test device side of test cable W2 is dedicated. It shows that it is connected to the tester connection part 144.
In FIG. 5A, in the test item A2, the test cables W1 and W2 are used, the test device side of the test cable W1 is connected to the measuring instrument connecting portion 142, and the test device side of the test cable W2 is dedicated. It shows that it is connected to the tester connection part 144.
Further, in the test item A3, the test cable W1 is used, and the test apparatus side of the test cable W1 is connected to the measuring instrument connection unit 142.

Similarly, FIG. 5B shows that test items B1 to B3 are performed for the device under test B.
5B shows that test cables W1 and W2 are used in the test item B1, the test device side of the test cable W1 is connected to the measuring instrument connecting portion 142, and the test device side of the test cable W2 is dedicated. It shows that it is connected to the tester connection part 144.
FIG. 5B shows that, in the test item B2, the test cable W2 is used, and the test device side of the test cable W2 is connected to the measuring instrument connecting portion 142.
FIG. 5B shows that, in the test item B3, the test cable W3 is used, and the test device side of the test cable W3 is connected to the measuring instrument connecting portion 142.

FIG. 6 is a diagram illustrating a cable related information table for each test item stored in the cable related information storage unit 300.
As shown in FIG. 6, the test item cable-related information table 420 includes the cable identification information of the test cables 162 used in each test item, and each test cable 162 includes the device under test 110 and the measuring device connection unit 142. A connector that knows the order (connection order) to be connected to each other, and the detailed shapes and positions of the mating connectors such as the DUT 110 and the measuring instrument connection 142 to which the connectors at both ends of each test cable 162 are connected Detailed position diagram is shown.
In this connection order, when a plurality of test cables 162 are connected to the test apparatus 12 and the device under test 110, the test apparatus side connector of the test cable 162 is connected to each connector such as the measuring instrument connection section 142, This is the order in which work can proceed efficiently when the device under test side connector is connected to each connector of the device under test 110.
For example, if the test cable W1 is connected after the test cable W1 is connected, the test cable W1 interferes with the test cable W2, and it becomes difficult to connect the test cable W2. The connection order is ahead of the connection order of the test cables W1.

The test item cable-related information table 420 indicates which connector of the device under test of each test cable 162 to be used is connected to which connector of the device under test, and the test apparatus of each cable 162 used. The connector to which the side connector is connected, such as the measuring instrument connection part 142, is shown.
For example, in the test items according to FIG. 7A (for example, tests performed on the device under test A), test cables W1 to W9 indicated by the cable identification information W1 to W9 are used, respectively. Further, the device under test side connector of the test cable W7 is connected to the connector “1J1” of the device under test 110, and the test device side connector of the test cable W7 is connected to the connector “J11” of the measuring device connection portion 142. .

  Further, for example, in the test items (for example, a test performed on the device under test B) according to FIG. 7B, test cables W31 to W39 respectively indicated by cable identification information W31 to W39 are used. Further, the device under test side connector of the test cable W35 is connected to the connector “1J7” of the device under test 110, and the test device side connector of the test cable W35 is connected to the connector “J21” of the dedicated tester connection part 144. The

Further, the detailed connector position diagram shows that when a plurality of cables 162 are connected to the test apparatus 12 and the device under test 110, the connectors at both ends of each cable 162 are mated connectors such as the device under test 110 and the measuring device connection portion 142. It is the figure which showed the detailed shape and position of the other party connector so that it can be found easily when it fits.
For example, when the cable W2 is to be connected (see FIG. 9), the connector position details showing the detailed shape and position of the connector “1J5” of the device under test 110 and the connector “J1” of the measuring device connection section 142. The figure “P2” is displayed on the screen of the controller 24.

The test item setting unit 302 (see FIG. 4) receives setting information indicating the test target 110 to be tested and the test items to be executed from the input / output device 256, and information related to the test to be performed (test Information).
This setting information is generated, for example, when an operator operates an input / output device 256 such as a keyboard.
The connection diagram display unit 304 accepts the test information from the test item setting unit 302 and corresponds to the test information by referring to the test item cable related information table 420 (FIG. 6) stored in the cable related information storage unit 300. A process for displaying on the input / output device 256 such as a display device a screen for displaying a connection diagram of the cable to be used and a connector connection state diagram (described later with reference to FIG. 7) is performed.
By confirming the connection cable connection diagram and the connector connection state diagram screen displayed on the input / output device 256, the operator can confirm the connection position of the entire test cable 162.
In addition, since the input / output device 256 displays the connection order of the cables 162, the operator can rearrange the prepared cables 162 in accordance with the connection order, thereby improving the efficiency of the cable connection work.

The necessary cable determination unit 310 accepts the test information from the test item setting unit 302, and the device under test 110 and test items indicated by the test information, and the cable related information table 410 for each device under test stored in the cable related information storage unit 300. From FIG. 5, the test cable 162 necessary for the test to be performed is determined.
For example, when the test information indicates the device under test A and the test item A1, the necessary cable determination unit 310 determines that the cables W1 and W2 are necessary.
Further, the necessary cable determination unit 310 outputs the necessary cable identification information of the test cable 162 to the necessary cable display unit 312.
The necessary cable display unit 312 uses the cable identification information from the necessary cable determination unit 310 to display the identification information of the test cable 162 necessary for the test to be performed on the input / output device 256 such as a display device. Perform the process.
By confirming the test cable 162 displayed on the input / output device 256, the operator can efficiently prepare the necessary test cable 162.

The connection order confirmation unit 330 determines the current connection order of the test cables 162 (that is, what number of test cables 162 should be connected in the connection order).
For example, the connection order confirmation unit 330 sets the initial value of the order counter value to n = 1, and increments the order counter value by one each time it is determined that the test cable 162 having the correct order exists in the vicinity of the test apparatus 12. Let
In addition, when the connection order confirmation unit 330 receives the cable identification information of the test cable 162 from the cable identification information reception unit 320, the connection order confirmation unit 330 determines whether or not the connection timing of the test cable 162 corresponding to the cable identification information is correct. to decide.
Specifically, the connection order confirmation unit 330 uses the test items indicated in the test information received from the test item setting unit 302 to store the cable related information table for each test item stored in the cable related information storage unit 300. Referring to 420 (FIG. 6), it is determined whether the connection order of the test cables 162 corresponding to the received cable identification information matches the current order counter value.

Furthermore, when the connection timing of the test cable 162 corresponding to the cable identification information is incorrect (that is, the connection order of the test cable 162 corresponding to the received cable identification information is If it does not match the current order counter value, a signal indicating a mismatch (cable mismatch signal) is generated and output to the connection order confirmation display unit 348.
On the other hand, when the connection timing of the test cable 162 corresponding to the cable identification information is correct (that is, the connection order of the test cable 162 corresponding to the received cable identification information is In the case of matching with the order counter value), a signal indicating a match (cable match signal) is generated and output to the connection order confirmation display unit 332.

In addition, the connection order confirmation unit 330 increases the order counter value by one (n = n + 1) when the cable match signal is generated.
Further, in this case, the connection order confirmation unit 330 refers to the test item cable related information table (FIG. 6) corresponding to the test item indicated by the test information, and determines the test cable 162 to be connected next. To do.
For example, the connection order confirmation unit 330 generates the connection order of the test cables W4 (sixth in the case of generating a cable match signal related to the cable identification information W4 of the test cable W4 in the test item corresponding to FIG. ) Is determined to be the cable W5.
Further, the connection order confirmation unit 330 outputs information (next connection order information) indicating the test cable 162 that is the next connection order to the connection order confirmation display unit 332.

The connection order confirmation display unit 332 displays an indication that the connection order of the test cables 162 is incorrect when the cable mismatch signal is received (for example, the cable color is changed to a red display). Processing for displaying on the device 256 is performed.
Thereby, the operator can easily confirm that the connection order of the test cables 162 to be connected is incorrect, and therefore the work efficiency of cable connection can be improved.
On the other hand, the connection order confirmation display unit 332 displays an indication that the connection order of the test cables 162 is correct (for example, the cable color is changed to green) when the cable match signal and the next connection order information are received. Processing for displaying on the input / output device 256 such as a device is performed. Further, an indication that the test cable 162 is the next connection order based on the next connection order information (for example, the cable color is changed to yellow display) is displayed on the input / output device 256 such as a display device. Process.
In addition, although not shown in the drawings, in the detailed position diagram of the mating connector of the test cable, an indication that the connection order of the test cables 162 is correct (for example, the cable color is changed to green display) is displayed on the display device or the like. Processing for displaying on the input / output device 256 may be performed. In the detailed position diagram of the mating connector of the test cable, an indication that the test cable 162 is the next connection order based on the next connection order information (for example, the cable color is changed to yellow display), Processing for displaying on the input / output device 256 such as a display device may be performed.
Thus, the operator can easily confirm the test cable 162 to be connected next, and therefore the work efficiency of the cable connection can be improved.

  The measurement information receiving unit 342 receives the measurement value measured by the measuring device 150 such as a scalar network analyzer or a digital multimeter via the input / output device 256 and outputs it to the electrical connection quality determination unit 344.

The electrical connection pass / fail judgment unit 344 connects the test cable 162 to the test apparatus 12 and the device under test 110, and then fits the test apparatus side connector of the test cable 162 and the connector such as the measuring instrument connection part 142 to each other. Check the electrical connection status of the test cable 162 and whether the connector of the device under test of the test cable 162 and the connector of the device under test 110 are in a good fit, and whether there is any disconnection or the like in the test cable 162 I do.
In addition, the electrical connection quality determination unit 344 confirms and measures the connection state between the test cable 162 and the test apparatus 12 and the device under test 110 using a measuring instrument such as a scalar network analyzer or a digital multimeter. Based on the measured value, the electrical connection quality is determined (see FIGS. 10 and 11 described later), and the determination result information is output to the electrical connection quality display unit 346.
The electrical connection quality display unit 346 performs processing for causing the input / output device 256 such as a display device to display determination result information regarding the electrical connection quality of the test cable 162 input from the electrical connection quality determination unit 344. Do.

The cable connection completion determination unit 360 determines whether the cable connection of all the test cables 162 has been completed.
Specifically, the cable connection completion determination unit 360 receives the test information from the test item setting unit 302, and uses the test item indicated by the test information to store the cable for each test item stored in the cable related information storage unit 300. With reference to the related information 420, it is determined whether or not the cable matching signals corresponding to the cable identification information of all the test cables 162 have been received from the connection order confirmation unit 330.
Further, the cable connection completion determination unit 360 generates information (cable connection completion information) indicating that the cable match signals of all the test cables 162 have been received, and outputs the information to the cable connection completion display unit 362.

The cable connection completion display unit 362 performs processing for displaying on the input / output device 256 such as a display device that the cable connection is completed based on the cable connection completion information from the cable connection completion determination unit 360.
Specifically, when the cable connection completion information is received, the cable connection completion display unit 362 performs processing for displaying the completion of cable connection on the input / output device 256 such as a display device in a sub window.
By displaying the cable connection completion information by the input / output device 256, it is possible to prevent malfunction such as starting a test in a state where the connection of the test cable 162 is not completed.

FIG. 7 is an example of a screen that displays a connection diagram and a connection state diagram of cables used.
As shown in FIG. 7, the connection diagram of the cables used indicates which connector of each of the test cables 162 used in the test is connected to the measuring instrument connecting portion 142 and the like and the device under test 110, and The connection order of the cable 162 for operation is shown. The connection state diagram of the cables used shows a state (connection state) in which each connector of the test cable 162 is fitted.
The screen shown in FIG. 7 is displayed on the input / output device 256 such as a display device by the processing of the connection diagram display unit 304.

FIG. 8 is a screen example in the case where the cable color is changed on the screen of FIG. 7 or the connector position detailed view is superimposed and displayed by the processing of the connection order confirmation unit 330.
As shown in FIG. 8, when the cable identification information is read from the test cable 162 in the correct order, the processing of the connection order confirmation display unit 332 displays the corresponding test cable 162 in the connection state diagram of FIG. The color is changed.
For example, when the cable identification information “W7” of the test cable W7 in the correct order is read, the connection order confirmation display unit 332 displays the cable of the cable W7 (part A2 in FIG. 8) in the connection state diagram of FIG. The color is changed to green, for example.

Further, when the cable identification information is read from the test cable 162 in the correct order, as shown in FIG. 8, the corresponding part of the test cable 162 that is the next connection order is processed by the connection order confirmation display unit 332. The display of is changed.
For example, when the cable identification information “W2” of the test cable W2 in the correct order is read, the connection order confirmation display unit 332 displays the corresponding part of the cable W2 that is the next connection order in the connection state diagram of FIG. For example, the color of part B) in FIG. 8 is displayed in yellow, and a detailed view of the connector position of the test cable W2 is superimposed on the screen.

[Test cable connection confirmation process]
The test cable connection confirmation processing by the cable connection preparation program 30 operating in the controller 24 described above will be described with reference to FIGS.
FIG. 9 is a flowchart showing a test cable connection confirmation process executed in the test system according to the first embodiment of the present invention. FIG. 10 is a flowchart showing the electrical connection check process executed in step S111 of FIG. FIG. 11 is a flowchart showing the electrical connection check process executed in step S111 of FIG.
Note that the order of the steps described below can be changed as appropriate (the same applies to other flowcharts).

In step S <b> 101, the operator performs a test item selection operation from the input / output device 256 of the controller 24.
In step S102, the input / output device 256 determines the cable identification information of the test cable 162 used in the test of the test item (initially the test item A1) and the device under test from the test item cable related information table 420 (FIG. 6). Each information of a connector, a measuring instrument connection part connector, a connection order, and a connector position detailed view is acquired. For example, in the example of the test item A1 in FIG. 6, the test cable W1 includes cable identification information “W1”, a device under test connector “1J8”, a measuring instrument connector “J2”, a connection order “8”, and Each information of the connector position detailed view “P1” is acquired. The test cables W2 to W9 are obtained in the same manner.

In step S103, through the processing of the connection diagram display unit 304, the input / output device 256 displays a cable connection diagram and a connection state diagram necessary for the set test items on the screen (see FIG. 7).
By checking the test cable 162 displayed on the input / output device 256, the operator can prepare the necessary test cable 162.
When the operator presses the start button 501 on the screen 500 shown in FIG. 7 in step S104, the order counter is set to n = 1 in the input / output device 256 by the processing of the connection order confirmation unit 330 in step S105. Is done.

In step S106, by the processing of the connection order confirmation unit 330, the input / output device 256 refers to the test item cable related information table 420 in FIG. 6 and changes the cable color of the test cable 162 to be connected first to yellow. At the same time, an instruction to display the detailed connector position diagram is output to the connection order confirmation display unit 332. The input / output device 256 changes the cable color of the predetermined test cable 162 to yellow in the used cable connection state diagram on the screen by the processing of the connection order confirmation display unit 332, and details of the connector position of the test cable 162 The figure is superimposed on the screen. (See Figure 8)
Here, the worker brings the test cable 162 to be connected first to the vicinity of the switching unit 140 and starts the work of attaching the test cable 162.

In step S107, the input / output device 256 causes the RFID reader 164 attached to the test cable 162 prepared by the operator to approach the tag reader 180 by the processing of the cable identification information receiving unit 320. Cable identification information is read from the RFID tag 164.
In step S108, by the processing of the connection order confirmation unit 330, the input / output device 256 determines whether or not the connection order of the test cables 162 corresponding to the cable identification information is correct. Advances to step S110, and if not (NO), the process advances to step S109.
In step S109, by the processing of the connection order confirmation display unit 332, the input / output device 256 changes the cable color of the corresponding test cable 162 to red to indicate that the connection order of the test cables 162 is incorrect. .
In step S110, the processing of the connection order confirmation display unit 332 causes the input / output device 256 to change the cable color of the corresponding test cable 162 to green in order to indicate that the test cable 162 is correct.

In step S111, the input / output device 256 performs an electrical connection check process, which will be described in detail later.
In step 112, the input / output device 256 determines whether all the test cables 162 have been connected by the processing of the cable connection completion determination unit 360. The process proceeds to S113, and if not connected (NO), the process proceeds to Step S114.
In step S113, the input / output device 256 displays in a sub-window that the connection of all the test cables 162 is completed by the processing of the cable connection completion display unit 362.
In step S114, by the process of the connection order confirmation unit 330, the input / output device 256 increments the order counter value by 1 (n = n + 1), and returns to the process of step S106.

Next, the electrical connection check process executed in step S111 in FIG. 9 will be described with reference to FIGS.
First, when the test cable 162 is correctly connected to the switching unit 140 of the test apparatus 12 and the input / output connector of the device under test 110, the input / output device 256 is connected to the test cable and the mating connector. A display indicating that the connection order of the test cables is correct is displayed on the detailed position diagram of the mating connector of the test cable. And in the case of a high impedance state, the process of FIG. 10 is performed.
In step S201, the input / output device 256 transmits a switching signal to the switching unit 140 by the processing of the electrical connection quality determination unit 344, and switches the connection on the measuring instrument side of the connected test cable 162 to the scalar network analyzer. I do.
In step S202, the input / output device 256 uses the scalar network analyzer to measure the reflected power with a minute power that does not destroy the input / output circuit by the processing of the electrical connection quality determination unit 344.
In step S203, by the process of the electrical connection quality determination unit 344, the input / output device 256 confirms the normal value of the reflected power of the connector unit to be measured, compares the normal value of the reflected power with the measured value, and the reflected power≈ In the case of input power, the process proceeds to step S204, and in the case where reflected power <input power and the measured reflected power is a value close to a normal value, the process proceeds to step S205.
In step S204, the input / output device 256 causes the corresponding test cable 162 to blink in the connection state diagram on the screen due to the incomplete connection by the processing of the electrical connection pass / fail display unit 332, and the process returns to step S202.
In step S <b> 205, the input / output device 256 displays the completion of the electrical connection of the corresponding test cable 162 in a subwindow by the processing of the electrical connection quality display unit 332.

On the other hand, when the resistance value when the test cable 162 is correctly connected to the switching unit 140 of the test device 12 and the input / output connector of the device under test 110 is constant, the input / output device 256 performs the processing of FIG. I do.
In step S301, the input / output device 256 transmits a switching signal to the switching unit 140 by the processing of the electrical connection quality determination unit 344, and switches the connection on the measuring instrument side of the connected test cable 162 to the digital multimeter. I do.
In step S <b> 302, the input / output device 256 measures the resistance value with a small amount of power that does not destroy the input / output circuit by the digital multimeter by the processing of the electrical connection quality determination unit 344. When a capacitive device such as a capacitor is inserted in series, the resistance is measured with an alternating current.
In step S303, the input / output device 256 confirms the normal value of the resistance value of the connector unit to be measured by the process of the electrical connection quality determination unit 344, compares the normal value of the resistance value with the measured value, and In this case, the process proceeds to step S304. If the measured resistance value is close to the normal value, the process proceeds to step S305.
In step S304, the input / output device 256 causes the corresponding test cable 162 to blink in the connection state diagram on the screen because the connection is incomplete due to the processing of the electrical connection pass / fail display unit 332, and the process returns to step S302.
In step S <b> 305, the input / output device 256 displays the completion of the electrical connection of the test cable 162 in a subwindow by the processing of the electrical connection quality display unit 332.
If the electrical connection of the test cable is correct, check that the electrical connection of the test cable is correct in the connection state diagram of the test cable and the mating connector or the detailed position of the mating connector of the test cable. While displaying the test cable in the next connection order.

  As described above, according to the test system according to the first embodiment of the present invention, the cable connection work when connecting a plurality of cables connecting the test apparatus and the device under test can be performed efficiently and reliably. it can.

  Note that the configuration and operation of the above-described embodiment are examples, and it is needless to say that the configuration and operation can be appropriately changed and executed without departing from the gist of the present invention.

1: Test system, 2: Computer, 3: Computer, 10: Test device, 12: Test device, 20: Controller, 22: Controller for device under test, 24: Controller, 30: Cable connection preparation program, 100: Test System: 110: device under test, 120, 120-1, 120-N: measuring device, 130: dedicated testing device, 140: switching unit, 142: measuring device connecting unit, 144: dedicated testing device connecting unit, 150, 150 -1,150-N: measuring device, 160: test cable, 162: test cable, 164: RFID tag, 180: tag reader, 250: main body, 252: CPU, 254: memory, 256: input / output device, 258 : Communication device, 260: Recording device, 262: Recording medium, 300: Cable related information storage unit, 302: Test item setting unit, 304: Connection diagram display unit, 310: Cable required determination unit, 312: Necessary cable display unit, 320: Cable identification information reception unit, 330: Connection order confirmation unit, 332: Connection order confirmation display unit, 342: Measurement information reception unit, 344: Electrical connection quality determination unit 346: Electrical connection pass / fail display section, 360: Cable connection completion determination section, 362: Cable connection completion display section, 410: Cable related information table for each device under test, 420: Cable related information table for each test item, 500: Screen 501: Start button 510: Screen.

Claims (3)

In a test system having a test device for testing a device under test and a plurality of test cables connecting the device under test and the test device,
A storage medium attached to each of the plurality of test cables and storing identification information for identifying the plurality of test cables, and the identification from the storage medium attached to each of the plurality of test cables A reader for reading information, and a scalar network analyzer or digital multimeter for checking the electrical connection of the test cable,
The test apparatus comprises:
The identification information of the test cable used in the test, the connection order information to which the test cable is to be connected, and the detailed position diagram of the mating connector to which the test cable is to be connected are stored in association with each other. Refer to the cable related information table based on the cable related information table and the identification information read by the reader, determine whether the test cable connection order is correct,
When the connection order of the test cables is correct, a display indicating that the connection order of the test cables is correct is displayed, while the electrical connection confirmation of the test cables is confirmed using the scalar network analyzer or the digital multimeter. Done
When the electrical connection of the test cable is correct, the test system is characterized by displaying that the electrical connection of the test cable is correct while displaying the test cable in the next connection order. . The test system according to claim 1, wherein the test apparatus includes:
Display means for displaying a connection state diagram of the test cable and the mating connector or display means for displaying a detailed position diagram of the mating connector of the test cable;
When the connection order of the test cables is correct, on the connection state diagram or the detailed position diagram, while indicating that the connection order of the test cables is correct,
Check the electrical connection of the test cable using the scalar network analyzer or the digital multimeter,
If the electrical connection of the test cable is correct, a display indicating that the electrical connection of the test cable is correct is displayed on the connection state diagram or the detailed position diagram, while the test cable of the next connection order is displayed. A test system characterized by performing display. In a test system having a test device for testing a device under test and a plurality of test cables connecting the device under test and the test device,
The identification information of the test cable used in the test, the connection order information to which the test cable is to be connected, and the detailed position diagram of the mating connector to which the test cable is to be connected are stored in association with each other. Refer to the cable related information table based on the cable related information table and the identification information read by the reader, determine whether the test cable connection order is correct,
If the test cable connection order is correct, a message indicating that the test cable connection order is correct is displayed, while a scalar network analyzer or digital multimeter is used to check the electrical connection of the test cable.
When the electrical connection of the test cable is correct, the test method is characterized by displaying that the electrical connection of the test cable is correct while displaying the test cable in the next connection order .