JP2007333674A - Cable connection diagnosis device and diagnosis system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect actual and potential failures related to cables, including degradations of contact parts for cabling to connection objects. <P>SOLUTION: A cable connection diagnosis device 1 includes a notification part 10, a control part 11, a storage part 12, an impedance measurement part 13 for measuring an impedance value between cable signal wires, a setting switch 14 for storing the measured impedance value in the storage part 12, and a power supply 15. Impedance values are computed with and without cabling to connection objects, and a threshold is calculated from the impedance values. According to the results of comparison of the measured impedance value of connected cables with the threshold, the cables and the status of connection between the connection objects and the cables are diagnosed, and cable connection failures and degradations are managed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a cable connection diagnostic apparatus and a diagnostic system for diagnosing cable connections between or within electronic devices used in medical systems, nuclear power systems, automobile systems, aircraft systems and the like that are not allowed to malfunction.

  Conventionally, in order to maintain electrical reliability, for example, Patent Document 1 discloses a movable cable for detecting a possibility of a device failure due to deterioration of a cable to a movable portion during a period in which the device is operating normally. A deterioration detection apparatus is disclosed.

  The movable cable deterioration detection device is provided in parallel with the movable cable connected between the movable part and the fixed part, and is provided with a deterioration detection cable that is more easily deteriorated than the cable, and a deterioration detection unit that detects the disconnection. It is possible to systematically determine an appropriate time to replace the cable by detecting the possibility of the device failure due to the deterioration of the cable to the movable part during the normal operation of the device. The structure which was made is described.

Also, when using a circuit board (Print Circuit Board) or cable as a part of the device in a movable cable deterioration detection device, if the number of connections exceeds a certain number of times, the connector will be worn and the device will not operate normally. In the product inspection process, the number of connections of these wiring connection portions is managed, and when a certain number of connections is exceeded, it is exchanged.
JP 2000-162121 A

  However, in the configuration described in Patent Document 1, the number of times of connection to the inspection target such as a board or a cable is described on the management sheet or the like each time the number of times of connection is managed. It is necessary to perform the work manually and it is difficult to strictly manage it. In an inspection apparatus with a large number of inspections, there is a case in which the contact of the connection portion is worn during the inspection and does not operate normally.

  In addition, since the inspection is performed by the configuration including the deterioration detection cable that is more easily deteriorated than the cable to be inspected and the deterioration detection means for detecting the disconnection, the cable to be inspected before the deterioration detection cable due to an accident or the like There is a problem that it does not work when disconnected.

  Further, the above-described conventional method only allows the specification of the deterioration point in the wire material accompanying the repeated movement of the cable itself, and cannot detect the deterioration of the contact portion caused by the repeated connection between the device and the cable. In other words, since cables used in inspection equipment for electronic devices are repeatedly attached and detached, the contact part deteriorates before the signal line in the cable deteriorates, so the conventional technology specifies that the cable contact part deteriorates. There was a problem that could not be done.

  The present invention is directed to solving the above-described problems of the prior art, and is capable of detecting a failure related to the cable including the deterioration of the contact portion connecting the connection target and the cable and the possibility of the cable connection. An object is to provide a diagnostic apparatus and a diagnostic system.

  In order to achieve the above object, a cable connection diagnosis apparatus according to claim 1 of the present invention includes an impedance measurement unit that measures an impedance value between signal lines of a cable connected to a connection target, and an impedance measurement unit. Comparing means for comparing the measured impedance value with a threshold value, and notifying means for notifying the comparison result of the comparing means are provided.

  Moreover, the cable connection diagnostic device according to claim 2 calculates a threshold value from each impedance value measured when the cable is connected to and disconnected from the connection target in the cable connection diagnostic device according to claim 1, A means for diagnosing a connection target and a cable state based on a comparison result of a threshold value and a measured impedance value when the cable is connected is provided.

  According to a third aspect of the present invention, there is provided the cable connection diagnostic apparatus according to the first or second aspect, further comprising voltage measuring means for measuring a voltage between the signal lines of the cable for measuring the impedance value. The impedance value of the cable connected to the connection target is measured only when it is confirmed that the connection target is powered off based on the measurement result of the means, and is compared with the threshold value.

  The cable connection diagnostic device according to any one of claims 4 to 6 is the cable connection diagnostic device according to any one of claims 1 to 3, wherein the cable connection diagnostic device has a value between an impedance value when the cable is connected and an impedance value when the cable is not connected. The threshold value is set to a value close to the impedance value when the cable is not connected, the threshold value is set to an intermediate value between the impedance value when the cable is connected and the cable is not connected, and There is provided a changing means for making the threshold value an arbitrary value.

  According to a seventh aspect of the present invention, there is provided the cable connection diagnostic apparatus according to any one of the first to sixth aspects, further comprising warning means for warning when the impedance value measured for the cable reaches a threshold value. And

  A cable connection diagnosis system according to claim 8 is a cable connection diagnosis system comprising the cable connection diagnosis device according to any one of claims 1 to 7 and a host device. In addition, a communication unit for transmitting the measured impedance value and threshold status information to the host device is provided, and a management unit for managing the cable connection based on the acquired status information is provided in the host device.

  A cable connection diagnosis system according to claim 9 is a cable connection diagnosis system comprising the cable connection diagnosis device according to any one of claims 1 to 7 and a host device. The communication means for transmitting the measured impedance value and threshold value status information to the host device by wireless communication is provided, and the host device is provided with a management means for managing the cable connection based on the acquired status information. .

  A cable connection diagnosis system according to claim 10 is the cable connection diagnosis system according to claims 8 and 9, wherein the management means associates the acquired status information with identification information for identifying the cable connection diagnosis device. It is characterized by managing connections.

  According to the above-described configuration, the deterioration status and connection status of the cable are monitored by the connected device and the impedance characteristics of the cable, so that not only the cable but also the degradation of the contact portion can be detected, and between the signal lines When the measured impedance value reaches the threshold value, the user is prompted to replace the cable or check the connection status between the device and the cable, and the replacement or connection can be confirmed before the cable is disconnected.

  According to the present invention, the deterioration status and connection status of a cable can be monitored by the impedance characteristics of the connected device and the cable, and the detection including not only the cable but also the deterioration of the contact portion can be performed. When the threshold value is reached, the user is prompted to confirm cable replacement or the connection status between the device and the cable, and can be replaced or checked before the cable is disconnected. If it is possible to measure, any cable or connection object can be applied.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIGS. 1A and 1B are block diagrams showing the connection configuration of the cable connection diagnostic apparatus according to Embodiment 1 of the present invention. The cable connection diagnostic device 1 according to the first embodiment shows a configuration for diagnosing cable connection of a power cable. As shown in FIGS. 1A and 1B, the power supply unit 2 a of the first device 2 is connected to the right side of the cable connection diagnostic device 1 via the power cable 3, and the second is connected to the left side via the power cable 4. Device 5 is connected.

  The cable connection diagnosis device 1 measures the impedance value between the signal lines, and notifies “NG (not connected)” if the measured value exceeds the threshold value, and “OK (connected)” otherwise. 10 is displayed to the user.

  When the connection state shown in FIG. 1A is good, the impedance value between the signal lines measured by the cable connection diagnostic device 1 is a measured value as shown in the logical connection form: Z1 × Z2 / (Z1 + Z2) [ Ω] and does not exceed a preset threshold value, and “OK” is displayed on the notification unit 10.

  Further, the connection state shown in FIG. 1B is when the connection is broken, and the connector contact portion of the power cable 4 is deteriorated to be in an open state. The cable connection diagnostic device 1 measures the impedance value between the signal lines, and displays “NG” on the notification unit 10 because the measured value is Z1 [Ω].

  FIGS. 2A and 2B are block diagrams showing a connection configuration of another cable connection diagnostic apparatus according to the first embodiment. In this example, a configuration in which the cable connection diagnosis device 1 diagnoses the cable connection connected to the first device 2 ′ and the second device 5 ′ by the USB cables 6 and 7 is shown.

  In the first embodiment, the power cable and the USB cable have been described as an example. However, any cable or connection can be used as long as the impedance value changes with respect to the connection target when the cable is connected and when the cable is not connected. Even if it is a target, it can be applied. In the above-described configuration example, the first device 2 and the second device 5 and the cable connection diagnosis device 1 are connected by a cable and separated, but the first device 2 or the second device 5 is shown. The cable connection diagnostic device 1 may be incorporated in any of the above and the configuration without one cable may be used.

  Further, the cable connection diagnostic device 1 according to the first embodiment has an impedance measurement unit that measures an impedance value between signal lines of a cable connected to a connection target, and an impedance value measured by the impedance measurement unit is changed. Impedance comparing means for comparing whether or not the threshold value is exceeded, and notifying means for notifying the comparison result of the impedance comparing means are provided.

  FIG. 3 is a block diagram showing the internal configuration of the cable connection diagnostic apparatus. As shown in FIG. 3, the cable connection diagnosis device 1 includes a notification unit 10 including a liquid crystal display (LCD), a control unit 11 including a one-chip microcomputer, and memory means including ROM, RAM, and the like. A storage unit 12, an impedance measurement unit 13 for measuring an impedance value between signal lines of the cable, a momentary type set SW (switch) 14 for storing the impedance value of the cable connection / non-connection state in the storage unit 12, and the like A power source 15 such as a battery serving as a circuit power source, cable connectors 16 and 17 for connecting cables, and a relay cable 18 for relaying between the cable connector 16 and the cable connector 17. The relay cable 18 and the impedance measuring unit 13 are configured. Is connected to measure the impedance value between the signal lines of the cable. To have.

  That is, the impedance measuring unit 13 corresponds to an impedance measuring unit that measures an impedance value between signal lines of a cable connected to the connection target, and the threshold value is determined by the control unit 11 and the storage unit 12 from the impedance value measured by the impedance measuring unit. It functions as a comparison means for comparing the value and determining the state of the cable connection.

  In the configuration example shown in FIG. 3 described above, one impedance measurement unit is provided so as to measure the impedance value between a pair of signal lines. However, the impedance measurement unit is configured to measure the impedance value between a plurality of signals. A plurality of 13 may be provided.

  4A, 4B, and 4C are diagrams showing changes in impedance values before and after connection of the cable according to the first embodiment, and FIG. (b) is a waveform diagram showing changes after cable deterioration, and (c) is a change in cable disconnection.

  As shown in FIG. 4 (a), the cable connection diagnostic device detects a connection state from the unconnected cable using an arbitrary impedance value set in advance as a threshold value. FIG. 4B shows that the impedance value at the time of cable connection approaches the impedance value before the cable connection due to the deterioration of the cable. FIG. 4C is an example showing a state when the cable is disconnected due to deterioration of the cable, and shows that there is no change in the impedance value before and after the cable connection.

  In addition, if the threshold value is set at the time of degradation before disconnection (there is no problem as an electrical connection between devices, but the impedance value is slightly increased due to an increase in contact resistance, etc.) It is possible to replace the cable before a failure occurs in the entire apparatus. For example, when the impedance value between the signal lines is 540 [Ω] before the cable is connected to the cable connection diagnostic device 1 and is 240 [Ω] after the connection, the impedance value measured by the impedance measuring unit 13 When the value becomes 400 [Ω] or more, the control unit 11 determines that the cable is not connected, and displays “NG” on the notification unit 10 even after connection. In the disconnected state, the impedance value between the signal lines is always 540 [Ω], and “NG” is always displayed on the notification unit 10.

FIG. 5 is a state transition diagram of the cable connection diagnostic apparatus according to the first embodiment. As shown in FIG. 5, the state (state) of the cable connection diagnostic device is divided into states (a) to (c).
(A) Standby state: idle state when cable is connected and not connected (b) configuration (Config) state: state where impedance value when cable is connected and not connected is measured, and threshold value is calculated (c) ) Check state: This is a state for detecting the current connection state of the connection target and the cable.

  Next, state transition will be described based on FIG. 5 with reference to FIG.

  When the set SW 14 is pressed and turned on by a user operation in the Standby state as the state (S1), the control unit 11 sets the display of the notification unit 10 to “NG” and sets the configuration flag: Confdone to “0”. ”, The impedance value at the time of non-connection measured by the impedance measurement unit 13 is stored in the storage unit 12, and the state transits to the Config state.

  As the state (S2), in the Config state, when the set SW 14 is pressed and turned on again by the user operation with the connection target and the cable connected, the control unit 11 detects the cable connection state and measures the impedance value. Then, the threshold value is calculated from the impedance difference between the connected state and the unconnected state, stored in the storage unit 12, and “1” is set in Confdone to transit to the Standby state.

  As an example of calculating the threshold value, when the impedance of the connected state of the cable is 400 [Ω] and the impedance of the unconnected state is 500 [Ω], the threshold value at which the cable is connected is (500−400) / 2 + 400 = 450 [Ω].

  In addition, the detection of the cable connection state is detected by subtracting several tens [Ω] from several [Ω] from the impedance value before connection stored in the storage unit 12, or after the connection stored in the storage unit 12. You may detect when it became the value of the impedance value vicinity.

  As the state (S3), when the configuration is completed in the Standby state (Confdone: “1”), the control unit 11 transitions to the Check state in response to an instruction to measure the impedance value automatically performed by a counting unit such as a timer. .

  As the state (S4), in the Check state, when the control unit 11 detects an impedance value lower than the threshold value, the control unit 11 determines that the cable is connected and sets the display of the notification unit 10 to “OK”.

  Alternatively, as the state (S5), in the Check state, when the control unit 11 detects an impedance value exceeding the threshold value, the control unit 11 determines that the cable is not connected, and sets the display of the notification unit 10 to “NG”. To do.

  As the state (S6), the state transitions to the Standby state upon completion of the impedance value measurement process.

  The state (Sid) is an idle state in which the control unit 11 waits for an instruction to measure the impedance value in the Standby state.

  In this way, since the impedance value between the signal lines is measured to diagnose the cable connection state, it is possible to manage the cable connection strictly.

  In the first embodiment, the cable connection / disconnection (disconnection) state on the second device 5 side illustrated in FIGS. 1A and 1B has been described as an example, but the same operation is performed on the first device 2 side as well. It is possible to manage the connection state even if they are combined.

  In this way, the threshold value is calculated from each impedance value measured when the cable is connected and not connected to the connection target, and the result of comparing this threshold value with the impedance value measured when the cable is connected It is possible to diagnose the connection status and cable status.

  FIG. 6 is a block diagram showing an internal configuration of the cable connection diagnostic apparatus according to Embodiment 2 of the present invention. In FIG. 6, the voltage diagnostic unit 19 is provided in the cable diagnostic device 1 shown in FIG. 3 described above, and the same reference numerals are given to the components corresponding to the components described in FIG. Is attached.

  As shown in FIG. 6, the cable connection diagnostic device 1 includes a voltage measurement unit 19 that measures a voltage between signal lines for measuring an impedance value, and based on the voltage measured by the voltage measurement unit 19 by the control unit 11. Control is performed so as not to misrecognize fluctuations in impedance values caused by turning on and off the power supply of the cable connection target.

  In the cable connection diagnostic apparatus 1 shown in FIG. 3 of the first embodiment described above, when the apparatus is turned on or off in the cable connection state, the impedance value varies depending on the connection target. There is a risk of misrecognizing connection and non-connection (disconnection).

  Therefore, the voltage measuring unit 19 is provided between the signal lines for measuring the impedance value, and the fluctuation of the impedance value when the apparatus is turned on and off is not measured based on the measurement signal.

  That is, the voltage measuring unit 19 functions as a voltage measuring unit that measures the signal voltage between the signal lines of the cable, and the control unit 11 turns off the connection target power source based on the voltage measured by the voltage measuring unit 19. The target cable connection state is confirmed only when it is confirmed.

  FIG. 7 is a state transition diagram of the cable connection diagnostic apparatus according to the second embodiment. As in the first embodiment described above, the state of the cable connection diagnostic device is divided into a Standby state, a Config state, and a Check state.

  The state transition will be described based on FIG. 7 with reference to FIG. Also in FIG. 7, the same reference numerals are assigned to the equivalent components corresponding to the state shown in FIG. 5 of the first embodiment.

  When the set SW 14 is pressed and turned on by a user operation in the Standby state as the state (S1), the control unit 11 sets the display of the notification unit 10 to “NG”, resets Confdone to “0”, The impedance value at the time of non-connection measured by the impedance measurement unit 13 is stored in the storage unit 12, and the state transits to the Config state.

  As the state (S2), in the Config state, when the set SW 14 is pressed and turned on again by the user operation with the connection target and the cable connected, the control unit 11 detects the cable connection state and measures the impedance value. Then, the threshold value is calculated from the impedance difference between the connected state and the unconnected state, stored in the storage unit 12, and “1” is set in Confdone to transit to the Standby state.

  As an example of calculating the threshold value, when the impedance of the connected state of the cable is 400 [Ω] and the impedance of the unconnected state is 500 [Ω], the threshold value at which the cable is connected is (500−400) / 2 + 400 = 450 [Ω].

  In addition, the detection of the cable connection state is detected by subtracting several tens [Ω] from several [Ω] from the impedance value before connection stored in the storage unit 12, or after the connection stored in the storage unit 12. You may detect when it became the value of the impedance value vicinity.

  As the state (S13), when the configuration is completed in the Standby state (Confdone: “1”) and the voltage measured by the voltage measuring unit 19 is at the off level, the control unit 11 uses a counting unit such as a timer. The state transits to the Check state in response to an instruction to measure the impedance value that is automatically performed.

  As the state (S4), in the Check state, when the control unit 11 detects an impedance value lower than the threshold value, the control unit 11 determines that the cable is connected and sets the display of the notification unit 10 to “OK”.

  Alternatively, as the state (S5), in the Check state, when the control unit 11 detects an impedance value exceeding the threshold value, the control unit 11 determines that the cable is not connected, and sets the display of the notification unit 10 to “NG”. To do.

  As the state (S6), the state transitions to the Standby state upon completion of the impedance value measurement process.

  The state (Sid) is an idle state in which the control unit 11 waits for an instruction to measure the impedance value in the Standby state.

  In this way, the voltage level between the signal lines is measured by the voltage measuring unit 19, and the state transition is performed only when the voltage level is in the off state, for example, turning on or off the power of the first device or the second device. Even if transient impedance fluctuations occur at the time, erroneous recognition can be eliminated.

  In the first and second embodiments, the threshold value is obtained from the impedance difference between when the cable is connected and when it is not connected, but as this threshold value, by setting the impedance value close to the state at the time of cable disconnection, In comparison with the threshold value, it is possible to reliably notify that there is a problem with the cable connection.

  As an example of calculating the threshold value, when the impedance of the connected state of the cable is 400 [Ω] and the impedance of the unconnected state is 500 [Ω], the threshold value at which the cable is connected is (500−400). / 50 + 400 = 405 [Ω]. By setting 405 [Ω] close to 400 [Ω] at the time of cable disconnection (not connected) as a threshold value, a state closer to electrical disconnection can be notified.

  In addition, as described in the first and second embodiments, the deterioration of the cable is recognized by setting the threshold value to 450 [Ω], which is an intermediate value between the impedance value when the cable is connected and the impedance value when the cable is not connected. Therefore, it is possible to prompt the user to replace the cable before a failure occurs in the connection between the devices.

  FIG. 8 is a block diagram showing the connection configuration of the cable connection diagnostic apparatus according to Embodiment 3 of the present invention, and FIG. 9 is a block diagram showing the internal configuration of the cable connection diagnostic apparatus. Moreover, the same code | symbol is attached | subjected to what has an equivalent function corresponding to the structural member demonstrated in FIG. 1, FIG.

  The cable connection diagnosis apparatus 1 shown in FIG. 9 can change the set threshold value by Limit + SW20 and Limit−SW21. That is, the control unit 11 detects the inputs of Limit + SW20 and Limit−SW21, and changes the threshold value to an arbitrary value, thereby fulfilling the function of the changing means.

FIG. 10 is a state transition diagram of the cable connection diagnosis apparatus according to the third embodiment. As shown in FIG. 10, the state (state) of the cable connection diagnostic device is divided into states (a) to (d). Corresponding to the state shown in FIG. 5 of the first embodiment, the same components are denoted by the same reference numerals.
(A) Standby state: idle state in the cable connection / non-connection state (b) Config state: impedance value in the cable connection / non-connection state is measured, a threshold value is calculated, and the notification unit 10 shown in FIG. Displays the current impedance value measured as a value and the threshold value as a Limit value.
(C) Check state: A state in which the current connection state between the connection target and the cable is detected, and the measured impedance value is displayed in the Curr value of the notification unit 10.
(D) Limit switch on state (Limit sw on): This is a state in which the threshold value is changed, and the Limit value of the notification unit 10 is incremented while Limit + SW 20 is on. While the Limit-SW 21 is on, the Limit value of the notification unit 10 is decremented.

  Next, state transition will be described based on FIG. 10 with reference to FIG.

  When the set SW 14 is pressed by a user operation in the Standby state as the state (S11), the control unit 11 sets the display of the notification unit 10 to “NG”, resets Confdone to “0”, and sets the impedance measurement unit The impedance value of the unconnected state measured by 13 is stored in the storage unit 12, and the impedance value is displayed on the notification unit 10 as a Curr value, and the state transits to the Config state.

  As the state (S12), in the Config state, when the set SW 14 is pressed and turned on again by the user operation with the connection target and the cable connected, the control unit 11 detects the connection state of the cable and stores the impedance value. Stored in the unit 12, and the impedance value is displayed as a Curr value in the notification unit 10, a threshold value is calculated from the impedance difference between the connected state and the unconnected state, stored in the storage unit 12, and the threshold value is stored. The limit value is displayed on the notification unit 10 and transitions to the Standby state.

  As the state (S3), when the configuration is completed in the Standby state (Confdone: “1”), the control unit 11 transitions to the Check state in response to an instruction to measure the impedance value automatically performed by a counting unit such as a timer. .

  As the state (S4), in the Check state, when the control unit 11 detects an impedance value lower than the threshold value, the control unit 11 determines that the cable is connected and sets the display of the notification unit 10 to “OK”.

  Alternatively, as the state (S5), in the Check state, when the control unit 11 detects an impedance value exceeding the threshold value, the control unit 11 determines that the cable is not connected, and sets the display of the notification unit 10 to “NG”. To do.

  As the state (S16), upon completion of the impedance value measurement process, the measured impedance value is displayed as a Curr value on the notification unit 10, and the state transits to the Standby state.

  As the state (S7), in the Standby state, when the Limit + SW 20 or the Limit-SW 21 is pushed by the user operation and is turned on, the state transits to the Limit sw on state.

  As a state (S8), when Limit + SW 20 is in the ON state in the Limit sw on state, the control unit 11 increments the Limit value that is a threshold value stored in the storage unit 12 and displayed on the notification unit 10.

  Alternatively, when the Limit-SW 21 is in the ON state in the Limit sw on state as the state (S9), the control unit 11 is the threshold value stored in the storage unit 12 and the Limit value displayed on the notification unit 10 Is decremented.

  When the control unit 11 detects that the Limit + SW 20 and the Limit−SW 21 are off in the Limit sw on state as the state (S10), the control unit 11 notifies the changed Limit value (threshold value). 10 Limit values and the storage unit 12 are set, and the state transits to the Standby state.

  The state (Sid) is an idle state in which the control unit 11 waits for an instruction to measure the impedance value in the Standby state.

  In the states (S3) and (S13) in the first and second embodiments, the impedance value measurement process is automatically instructed by a counting means such as a timer. It is also possible to instruct the impedance value measurement process even after the process such as the above change is performed.

  As described above, the threshold value set by the formula for calculating the threshold value incorporated in the cable connection diagnostic device 1 in advance can be arbitrarily changed. For example, when the cable is slightly deteriorated, the threshold value is replaced. This is effective when more detailed cable connection management is required.

  Further, since the current value (Curr value) of the measured cable impedance value and the threshold value (Limit value) indicating the replacement time are displayed together on the notification unit 10 of the cable connection diagnosis device 1, the user can indicate the connection status. Easy to grasp.

  FIG. 11 is a block diagram showing the internal configuration of the cable connection diagnostic apparatus according to Embodiment 4 of the present invention. The cable connection diagnostic device 1 shown in FIG. 11 is a device in which a buzzer 22 is newly provided in the configuration shown in FIG. 9 in the above-described third embodiment. The buzzer 22 is sounded to warn the user when the threshold is reached (when disconnected or not connected).

  By configuring in this way, according to the fourth embodiment, in the cable connection diagnostic device 1 of the above-described third embodiment, the cable connection status is not known unless the user reads the display of the notification unit 10. It is also assumed that the cable is not replaced without noticing that it is time to replace it.

  Therefore, a warning means including a buzzer 22 is provided, and a warning is given when the impedance value between the signal lines of the cable reaches a threshold value (in the case of the buzzer 22, a warning sound is sounded) to alert the cable replacement time. be able to.

  That is, the control unit 11 and the buzzer 22 serve as a warning unit that warns when the impedance value measured by the impedance measurement unit 13 reaches a preset threshold value.

  FIG. 12 is a state transition diagram of the cable connection diagnostic apparatus according to the fourth embodiment. As in the third embodiment described above, the state (state) of the cable connection diagnostic device is divided into a Standby state, a Config state, a Check state, and a Limit swon state. Also, in FIG. 12, the same reference numerals are assigned to the equivalent components corresponding to the state shown in FIG.

  Next, state transition will be described based on FIG. 12 with reference to FIG.

  When the set SW 14 is pressed and turned on by the user operation in the Standby state as the state (S11), the control unit 11 sets the display of the notification unit 10 to “NG”, resets Confdone to “0”, The impedance value of the unconnected state measured by the impedance measuring unit 13 is stored in the storage unit 12 and the impedance value is displayed as a Curr value on the notification unit 10 and transits to the Config state.

  As the state (S12), in the Config state, when the set SW 14 is pressed and turned on again by the user operation with the connection target and the cable connected, the control unit 11 detects the connection state of the cable and stores the impedance value. Stored in the unit 12, and the impedance value is displayed as a Curr value in the notification unit 10, a threshold value is calculated from the impedance difference between the connected state and the unconnected state, stored in the storage unit 12, and the threshold value is stored. The limit value is displayed on the notification unit 10 and transitions to the Standby state.

  As the state (S23), when the configuration is completed in the Standby state (Confdone: “1”), the control unit 11 operates the buzzer 22 according to an instruction to measure and process the impedance value automatically performed by a counting unit such as a timer. Transition to the Check state as the state.

  As the state (S14), in the Check state, when the control unit 11 detects an impedance value lower than the threshold value, the control unit 11 determines that the cable is connected, sets the display of the notification unit 10 to “OK”, and sets the buzzer 22 Set it off.

  Alternatively, as the state (S15), in the Check state, when the control unit 11 detects an impedance value exceeding the threshold value, the control unit 11 determines that the cable is not connected, and sets the display of the notification unit 10 to “NG”. In addition, the buzzer 22 is turned on.

  As the state (S16), upon completion of the impedance value measurement process, the measured impedance value is displayed as a Curr value on the notification unit 10, and the state transits to the Standby state.

  As the state (S7), in the Standby state, when the Limit + SW 20 or the Limit-SW 21 is pushed by the user operation and is turned on, the state transits to the Limit sw on state.

  When the Limit + SW 20 is ON in the Limit sw on state as the state (S8), the control unit 11 increments the Limit value that is the threshold value stored in the storage unit 12 and displayed on the notification unit 10. .

  Alternatively, when the Limit-SW 21 is in the ON state in the Limit sw on state as the state (S9), the control unit 11 is the threshold value stored in the storage unit 12 and the Limit value displayed on the notification unit 10 Is decremented.

  When the control unit 11 detects that the Limit + SW 20 and the Limit-SW 21 are in the off state in the Limit sw on state as the state (S10), the control unit 11 notifies the changed Limit value (threshold value). 10 Limit values and the storage unit 12 are set, and the state transits to the Standby state.

  In the state (S15) described above, if the buzzer 22 is turned on when the measured impedance value is greater than or equal to the threshold value, a warning sound can be sounded to prompt the user to connect or replace the cable.

  In this way, it is possible to prompt the user to check the cable connection status or replace the cable with a warning sound when the cable connection between the devices is in a disconnected state or a deteriorated state.

  FIG. 13 is a block diagram showing a schematic configuration of a cable connection diagnosis system according to Embodiment 5 of the present invention. In the fifth embodiment, when a system using a cable connection diagnostic device is configured, the connection status can be managed by the system, not by a person.

  As shown in FIG. 13, the cable connection diagnosis system includes a cable connection diagnosis device 1, first and second devices 2 and 5 for connecting a cable to be diagnosed, and a third device 30 for diagnosing the connection status. . The function of the third device 30 may be incorporated in either the first device 2 or the second device 5.

  The cable connection diagnosis apparatus 1 is provided with a communication control unit 23 newly in the cable connection diagnosis apparatus shown in FIG. The third device 30 includes a control unit 31 and a display unit 33. The control unit 31 includes a computer including a CPU, a ROM, and a RAM, and includes a management unit 32 that is realized by executing a management program. .

  The communication control unit 23 of the cable connection diagnostic device 1 and the management unit 32 of the third device 30 are connected to be communicable via a communication line. The management unit 32 acquires the impedance value between the signal lines of the cable from the cable connection diagnostic device 1 through the communication line, manages the connection status between the devices, and displays it on the display unit 33.

  FIG. 14 is a state transition diagram of the cable connection diagnosis apparatus according to the fifth embodiment. A communication (Communicate) state is added to the Standby state, Config state, Check state, and Limit swon state of the cable connection diagnostic device in the third embodiment described above.

  This Communicate state is a state in which communication is performed with the outside of the cable connection diagnostic device 1 through the communication control unit 23, and status information such as the current impedance value and threshold value of the Curr value and Limit value displayed on the notification unit 10 is displayed. Is output.

  Next, state transition will be described based on FIG. 14 with reference to FIG. As described above, since the Communicate state is added to the state transition shown in FIG. 10 of the third embodiment, the same reference numerals are given to the equivalent parts corresponding to the states shown in FIG. Omitted and different points will be described.

  As a state (S31), when the control unit 11 detects a status read request from the control unit 31 of the third device 30 through the communication control unit 23, the control unit 11 transits to the Communicate state.

  As the state (S32), in the Communicate state, the control unit 11 outputs status information such as the current impedance value and threshold value of the Curr value and Limit value to the control unit 31 of the third device 30 through the communication control unit 23.

  As the state (S33), after the status information output process, the process returns to the Standby state.

  FIG. 15 is a flowchart showing the processing operation of the management unit of the third device according to the fifth embodiment. The operation will be described with reference to FIG.

  The management unit 32 communicates with the cable connection diagnostic device 1 via the communication control unit 23 at an arbitrary timing by a counting means such as a timer, and the current impedance value of the Curr value and the Limit value is determined by a status read request. A threshold value is acquired (S41).

  The management unit 32 compares the acquired Curr value with the Limit value (S42). If the Curr value has not reached the Limit value (No in process S42), the process is terminated.

  If the Curr value is equal to or greater than the Limit value (Yes in process S42), the control unit 31 causes the display unit 33 to display a message dialog prompting the user to confirm the connection status (S43), and the process ends.

  As described above, the control unit 31 side of the third device 30 manages the cable connection status, and when the cable connection status reaches a threshold value, the third device 30 automatically notifies the user. Therefore, it is possible to prompt the user to exchange the cable and confirm the connection status. Therefore, even if the user overlooks the display on the notification unit 10 of the cable connection diagnostic device 1, the connection status can be surely known.

  In addition, as arbitrary timing in process S41, you may make it synchronize with the timing which instruct | indicates the measurement process of an impedance value in the state (S3) of the cable connection diagnostic apparatus 1, Thereby, the result of having diagnosed the cable is immediately. The third device 30 can grasp this.

  Further, as another example in the fifth embodiment, in place of the communication line of the cable connection diagnosis system shown in FIG. 13, signal exchange between the cable connection diagnosis device 1 and the third device 30 is performed by wireless communication. The configuration is shown in FIG.

  As shown in FIG. 16, in order to perform wireless communication, each of the cable connection diagnosis device 1 and the third device 30 is provided with communication control units 24 and 34 such as wireless LAN and infrared communication. The other operation processes are the same as described above, and thus description thereof is omitted.

  FIG. 17 is a block diagram showing a schematic configuration of a cable connection diagnosis system according to Embodiment 6 of the present invention. The cable connection diagnostic system of the sixth embodiment includes a radio frequency identification (RFID) tag unit 25 in the cable connection diagnostic device 1, and the RFID tag unit 25 has a Curr value (measured current impedance value), Limit value (threshold value) status information and device-specific identification information (ID) are stored as RFID tags, and these information can be acquired by wireless communication (wireless).

  The third device 30 is provided with an RFID reader / writer 35, and the RFID reader / writer 35 acquires the ID and status information from the RFID tag unit 25 and sends them to the management unit 32. The management unit 32 stores the ID and status information sent from the RFID reader / writer 35 and manages each of the plurality of cable connection diagnostic apparatuses 1.

  That is, the management unit 32 functions as a means for managing the status information transmitted from the cable connection diagnostic device 1 by associating the identification information of the cable connection diagnostic device with the status information. As described above, when the information of the plurality of cable connection diagnosis apparatuses 1 is collectively managed, it is efficient to use the RFID system as the communication control unit as the identification unit.

FIG. 18 is a state transition diagram of the cable connection diagnosis apparatus according to the sixth embodiment. The sixth embodiment is divided into the states (a) to (d) as in FIG. 10 of the third embodiment.
(A) Standby state: idle state in the cable connection / non-connection state (b) Config state: impedance value in the cable connection / non-connection state is measured, a threshold value is calculated, and the curr is notified to the notification unit 10 shown in FIG. The impedance value measured as the value and the threshold value as the Limit value are displayed, and the status information is set in the RFID tag unit 25.
(C) Check state: a state in which the current connection state between the connection target and the cable is detected, the measured impedance value is displayed in the Curr value of the notification unit 10, and this status information is set in the RFID tag unit 25.
(D) Limit sw on state: This is a state in which the threshold is changed, and the Limit value of the notification unit 10 is incremented while Limit + SW 20 is on. While the Limit-SW 21 is on, the Limit value of the notification unit 10 is decremented.

  Next, state transition will be described based on FIG. 18 with reference to FIG. Moreover, the same code | symbol is attached | subjected to the equivalent thing corresponding to the state shown in FIG. 10 of above-mentioned Embodiment 3. FIG.

  When the set SW 14 is pressed and turned on by the user operation in the Standby state as the state (S11), the control unit 11 sets the display of the notification unit 10 to “NG”, resets Confdone to “0”, The impedance value of the unconnected state measured by the impedance measuring unit 13 is stored in the storage unit 12 and the impedance value is displayed as a Curr value on the notification unit 10 and transits to the Config state.

  As the state (S22), in the Config state, when the set SW 14 is pressed and turned on again by the user operation with the connection target and the cable connected, the control unit 11 detects the connection state of the cable and stores the impedance value. Stored in the unit 12, and the impedance value is displayed as a Curr value in the notification unit 10, a threshold value is calculated from the impedance difference between the connected state and the unconnected state, stored in the storage unit 12, and the threshold value is stored. The information is displayed as a limit value on the notification unit 10 and the curr value and the status information of the limit value are stored in the RFID tag unit 25, and a transition is made to the standby state.

  As the state (S3), when the configuration is completed in the Standby state (Confdone: “1”), the control unit 11 transits to the Check state in response to an instruction to measure and process the impedance value automatically performed by a counting unit such as a timer. .

  As the state (S4), in the Check state, when the control unit 11 detects an impedance value lower than the threshold value, the control unit 11 determines that the cable is connected and sets the display of the notification unit 10 to “OK”.

  Alternatively, as the state (S5), in the Check state, when the control unit 11 detects an impedance value exceeding the threshold value, the control unit 11 determines that the cable is not connected, and sets the display of the notification unit 10 to “NG”. To do.

  As the state (S26), upon completion of the impedance value measurement process, the measured impedance value is displayed as the Curr value on the notification unit 10, and the Curr value is stored in the status information of the RFID tag unit 25, and the state transits to the Standby state. .

  As the state (S7), in the Standby state, when the Limit + SW 20 or the Limit-SW 21 is pushed by the user operation and is turned on, the state transits to the Limit sw on state.

  As a state (S8), when Limit + SW 20 is in the ON state in the Limit sw on state, the control unit 11 increments the Limit value that is a threshold value stored in the storage unit 12 and displayed on the notification unit 10.

  Alternatively, when the Limit-SW 21 is in the ON state in the Limit sw on state as the state (S9), the control unit 11 is the threshold value stored in the storage unit 12 and the Limit value displayed on the notification unit 10 Is decremented.

  When the control unit 11 detects that the Limit + SW 20 and the Limit−SW 21 are in the off state in the Limit sw on state as the state (S20), the control unit 11 notifies the changed Limit value (threshold value). The limit value is set in the storage unit 12 and the limit value is stored in the status information of the RFID tag unit 25, and a transition is made to the Standby state.

  FIG. 19 is a flowchart showing the processing operation of the management unit of the third device according to the sixth embodiment. The operation will be described with reference to FIG.

  The management unit 32 communicates with each of the plurality of cable connection diagnostic apparatuses 1 at an arbitrary timing by the RFID reader / writer 35, and acquires ID and status information (Curr value, Limit value impedance value, threshold value). (S51).

  The management unit 32 compares the acquired Curr value with the Limit value (S52). If the Curr value has not reached the Limit value (No in step S52), the process ends.

  If the Curr value is equal to or greater than the Limit value (Yes in process S52), the control unit 31 causes the display unit 33 to display a message dialog prompting the user to confirm the connection status (S53), and the process ends.

  By using the RFID system in this way, the control unit 31 side of the third device 30 manages the connection status of a plurality of cables wirelessly, and when the cable connection status reaches a threshold value, the third device Since the user can be automatically prompted to replace the cable or confirm the connection status at 30, the connection status can be surely known even if the user overlooks the display of the cable connection diagnostic device 1.

  Since the RFID system is used, information such as the Limit value in the cable connection diagnostic device 1 can be set in the storage unit 12 by providing the reverse configuration described above.

  The cable connection diagnostic device and the diagnostic system according to the present invention can monitor the deterioration status of the cable and the connection status by the impedance characteristics of the connected device and the cable, and can detect not only the cable but also the deterioration of the contact portion. In addition, when the measured impedance value reaches the threshold value, the user is prompted to replace the cable or check the connection status between the device and the cable. It is useful as a diagnostic device for cable connection between devices or in electronic devices.

1 is a block diagram showing a connection configuration of (OK) and (b) of “NG” of the cable connection diagnostic device according to the first embodiment of the present invention. The block diagram which shows the connection structure of (OK) of another cable connection diagnostic apparatus in this Embodiment 1, and (b) is "NG". The block diagram which shows the internal structure of the cable connection diagnostic apparatus in this Embodiment 1. (A) of the first embodiment is a waveform diagram showing a change in impedance value before cable deterioration, (b) after cable deterioration, and (c) when the cable is disconnected. State transition diagram of the cable connection diagnostic device according to the first embodiment The block diagram which shows the internal structure of the cable connection diagnostic apparatus in Embodiment 2 of this invention State transition diagram of cable connection diagnostic device according to Embodiment 2 The block diagram which shows the connection structure of the cable connection diagnostic apparatus in Embodiment 3 of this invention The block diagram which shows the internal structure of the cable connection diagnostic apparatus in this Embodiment 3. State transition diagram of cable connection diagnostic device in Embodiment 3 The block diagram which shows the internal structure of the cable connection diagnostic apparatus in Embodiment 4 of this invention State transition diagram of cable connection diagnostic device in Embodiment 4 The block diagram which shows schematic structure of the cable connection diagnostic system in Embodiment 5 of this invention. State transition diagram of cable connection diagnostic device in Embodiment 5 The flowchart which shows the processing operation of the management part of the 3rd apparatus in this Embodiment 5. The block diagram which shows schematic structure of another cable connection diagnostic system in this Embodiment 5. Schematic configuration of a cable connection diagnosis system according to Embodiment 6 of the present invention State transition diagram of cable connection diagnostic device in Embodiment 6 The flowchart which shows the processing operation of the management part of the 3rd apparatus in this Embodiment 6.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cable connection diagnostic apparatus 2, 2 '1st apparatus 2a Power supply unit 3, 4 Power cable 5, 5' 2nd apparatus 6, 7 USB cable 10 Notification part 11, 31 Control part 12 Storage part 13 Impedance measurement part 14 Set SW
15 Power supply 16, 17 Cable connector 18 Relay cable 19 Voltage measurement unit 20 Limit + SW
21 Limit-SW
22 buzzer 23, 24, 34 communication control unit 25 RFID tag unit 30 third device 32 management unit 33 display unit 35 RFID reader / writer

Claims (10)

  Impedance measurement means for measuring an impedance value between signal lines of cables connected to a connection target, comparison means for comparing the impedance value measured by the impedance measurement means with a threshold value, and a comparison result of the comparison means are notified. A cable connection diagnostic device comprising a notification means.   A threshold value is calculated from each impedance value measured when the cable is connected and not connected to the connection target, and the connection target and the connection target are calculated according to a comparison result between the threshold value and the measured impedance value when the cable is connected. 2. The cable connection diagnosis apparatus according to claim 1, further comprising means for diagnosing the state of the cable.   The voltage measuring means for measuring the voltage between the signal lines of the cable for measuring the impedance value, and the measurement result of the voltage measuring means is connected to the connection target only when it is confirmed that the connection target is powered off. 3. The cable connection diagnosis apparatus according to claim 1, wherein the impedance value of the cable is measured and compared with a threshold value.   A threshold value between the impedance value when the cable is connected and the impedance value when the cable is not connected, wherein the threshold value is a value close to the impedance value when the cable is not connected, The cable connection diagnostic device according to claim 1, 2, or 3.   A threshold value between the impedance value when the cable is connected and the impedance value when the cable is not connected, and the threshold value is an intermediate value between the impedance value when the cable is connected and when the cable is not connected. The cable connection diagnostic device according to claim 1, 2, or 3.   A threshold value that is a value between an impedance value when the cable is connected and an impedance value when the cable is not connected, and a changing unit that makes the threshold value an arbitrary value is provided. Item 4. The cable connection diagnostic device according to item 1, 2 or 3.   The cable connection diagnosis apparatus according to claim 1, further comprising a warning unit that warns when an impedance value obtained by measuring the cable reaches a threshold value. A cable connection diagnostic system comprising the cable connection diagnostic device according to any one of claims 1 to 7 and a host device,
The cable connection diagnostic device is provided with communication means for transmitting measured impedance value and threshold status information to the host device, and the host device is provided with management means for managing cable connection according to the acquired status information A cable connection diagnostic system characterized by that. A cable connection diagnostic system comprising the cable connection diagnostic device according to any one of claims 1 to 7 and a host device,
The cable diagnostic device is provided with communication means for transmitting the measured impedance value and threshold value status information to the host device by wireless communication, and the host device manages the cable connection based on the acquired status information. A cable connection diagnosis system characterized by comprising   The cable connection diagnosis system according to claim 8 or 9, wherein the management means manages the cable connection in association with the acquired status information in correspondence with identification information for identifying the cable connection diagnosis device.

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