JP2017211243A - Lightening surge tester and circuit for coaxial port thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform a lightning surge test between a coaxial port and other ports on a device to be tested that is provided with the coaxial port and other ports.SOLUTION: In order to perform a lightning surge test between the coaxial port and the external connection port of a device to be tested that includes a coaxial port to which a first external apparatus is connected and at least one external connection port to which a second external apparatus is connected, a lightning surge tester is used that comprises: a lightning surge generator for generating a lightning surge between a first terminal and a second terminal; a circuit for the coaxial port which is connected between the first terminal of the lightning surge generator and the coaxial port, terminates the coaxial port in correspondence to the first external apparatus, and applies the lightning surge to the coaxial port via an external conductor of a coaxial cable; and a circuit for the external connector port which is connected between the external connection port and the second terminal of the lightning surge generator and includes a coupling circuit for limiting the application destination of the lightning surge to the external connection port.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a lightning surge test apparatus for conducting a lightning surge test between a plurality of ports with respect to a device under test having a plurality of ports including a coaxial port, and a coaxial coupling circuit thereof.

  In recent years, with the spread of Internet technology, it has become possible to provide voice call services and video distribution services via the Internet. For use of such a service, for example, a home communication device such as a home gateway in which functions of a line termination device and a broadband router are integrated is often used. In this case, the in-home communication device includes a plurality of ports such as a coaxial port for television, an analog telephone port for voice calls, an Ethernet (registered trademark) port for the Internet, and a power supply port.

Japanese Patent Laid-Open No. 9-519934

  Standards for testing the overvoltage tolerance (including current) for each of the above ports are agreed by international standards such as ITU-T. Specifically, in ITU-T Recommendation K.44, the lightning surge test method in the above test is specified, and for analog telephone ports, Ethernet ports, and power supply ports, the overvoltage tolerance to be required for each port is determined. It has been.

  However, a method for conducting a lightning surge test between the coaxial port as an extension and another port has not yet been clearly defined for international standards such as ITU-T. Therefore, the case where the overvoltage tolerance of a coaxial port is not ensured appropriately is assumed.

  The present invention has been made paying attention to the above circumstances, and its object is to provide a lightning surge between a coaxial port and another port for a device under test having a plurality of ports including a coaxial port. The object is to provide a lightning surge test device and a circuit for its coaxial port which can be tested.

  To achieve the above object, according to a first aspect of the present invention, there is provided a device under test including a coaxial port to which a first external device is connected and at least one external connection port to which a second external device is connected. In order to perform a lightning surge test between the coaxial port and the external connection port of the device, a lightning surge generator that generates a lightning surge between the first terminal and the second terminal, and the lightning surge It is connected between the first terminal of the generator and the coaxial port, terminates the coaxial port corresponding to the first external device, and transmits the lightning surge to the coaxial through the outer conductor of the coaxial cable. A coaxial port circuit to be applied to the port, and a coupling circuit connected between the external connection port and the second terminal of the lightning surge generator, and limiting the application destination of the lightning surge to the external connection port For external connection port A lightning surge test wherein the lightning surge generated from the lightning surge generator is applied between the coaxial port and the external connection port via the coaxial port circuit and the external connection port. It constitutes a device.

  According to a second aspect of the present invention, when the device under test includes a plurality of external connection ports, a plurality of external connection port circuits connected to each of the plurality of external connection ports and the lightning surge generator A switch arranged between the second terminal and selectively connecting the plurality of external connection port circuits and the second terminal of the lightning surge generator; It is.

  According to a third aspect of the present invention, in the second aspect, the lightning surge generator is a test object among the plurality of external connection ports from among a plurality of types of lightning surges set in different waveforms in advance. In conjunction with the lightning surge selection means corresponding to the external connection port and the lightning surge selection operation, the external connection port to be tested is connected to the second terminal of the lightning surge generator. Therefore, a means for switching control of the switch is provided.

  According to a fourth aspect of the present invention, the coaxial port circuit further includes means for variably setting a resistance value for terminating the coaxial port.

  According to a fifth aspect of the present invention, the lightning surge generator further includes a circuit that alternately switches connection of the first terminal and the second terminal to the coaxial port circuit and the external connection port circuit. It is a thing.

  According to a sixth aspect of the present invention, there is provided a coaxial port circuit used in any one of the first to fifth aspects, the first coaxial cable connected to the coaxial port, and the first coaxial cable. A second coaxial cable connected to one external device, an application terminal for a lightning surge generated by the lightning surge generator provided on an outer conductor of the first coaxial cable, and the first coaxial cable Termination means for terminating the first external device between the center conductor and the outer conductor, and the first coaxial cable and the second coaxial cable during the lightning surge application period. A circuit for a coaxial port is configured to include a switching unit that disconnects the first coaxial cable and connects the first coaxial cable to the second coaxial cable after the lightning surge application is completed.

  According to a seventh aspect of the present invention, there is provided a circuit for disconnecting the connection with the lightning surge generator when the coaxial port circuit in the sixth aspect connects the first coaxial cable to the second coaxial cable. The coaxial port circuit is further provided.

  According to the first aspect of the present invention, a lightning surge can be applied between the coaxial port and the external connection port of the device under test using the lightning surge test device having the above-described configuration. For a coaxial port, by applying a lightning surge through the coaxial port circuit, a lightning surge test can be performed in a state equivalent to a state in which an external device using a coaxial cable is connected. For ports, by applying a lightning surge through each external connection port circuit, a lightning surge test with the coaxial port can be performed without applying a lightning surge to each opposing device. it can. That is, the lightning surge test between the coaxial port and the other external connection port, which has not been considered so far, can be accurately performed. Therefore, the lightning surge test between the coaxial port of the device under test and the external connection port can be performed in a test system that matches the actual environment, and can be used in the test environment (for example, the person, place, and device performing the test). It can be performed with good reproducibility without being influenced.

  According to the second aspect of the present invention, when the device under test includes a plurality of external connection ports, the plurality of external connection port circuits connected to each of the plurality of external connection ports and the lightning surge generator And a switch that selectively connects the plurality of external connection port circuits and the second terminal of the lightning surge generator. By providing the switch, the work of switching the connection between the plurality of external connection port circuits and the second terminal of the lightning surge generator each time is reduced, so that the lightning surge test can be performed efficiently. it can.

  According to a third aspect of the present invention, in the second aspect, the lightning surge generator is a test object among the plurality of external connection ports from among a plurality of types of lightning surges set in advance to different waveforms. In conjunction with the lightning surge selection operation corresponding to the external connection port, the external connection port to be tested is connected to the second terminal of the lightning surge generator. Means for switching control of the switch to be connected. Accordingly, since the plurality of external connection ports and a plurality of types of lightning surges corresponding to each of the plurality of external connection ports can be switched in conjunction with each other, a lightning surge test can be performed efficiently and reliably in a short time. be able to.

  According to a fourth aspect of the present invention, the coaxial port circuit further includes means for variably setting a resistance value for terminating the coaxial port. Therefore, a lightning surge test can be performed corresponding to various types of coaxial ports in the device under test.

  According to a fifth aspect of the present invention, the lightning surge generator further includes a circuit for alternately switching the connection of the first terminal and the second terminal to the coaxial port circuit and the external connection port circuit. Prepare. Therefore, the lightning surge application direction can be changed without changing the connection.

  According to a sixth aspect of the present invention, there is provided a circuit for a coaxial port of a lightning surge test apparatus, the first coaxial cable connected to the coaxial port and the second connected to the first external device. A coaxial cable, an application terminal for applying a lightning surge generated by the lightning surge generator, provided on an outer conductor of the first coaxial cable, a central conductor of the first coaxial cable, and the outer Terminating means for terminating the first external device between the conductor and the first coaxial cable and the second coaxial cable are separated from each other during the lightning surge application period, and the lightning A coaxial coupling circuit is provided that includes first switching means for connecting the first coaxial cable to the second coaxial cable after the application of surge. Since this coaxial coupling circuit can switch the lightning surge generator and the first external device connected to the coaxial port by the first switching means, the operation of the device under test after performing the lightning surge test Confirmation can be performed smoothly.

  According to a seventh aspect of the present invention, when the coaxial port circuit connects the first coaxial cable to the second coaxial cable, the second switching means disconnects the connection with the lightning surge generator. Is further provided. Since the connection with the lightning surge generator is disconnected by the second switching means, the operation of the device under test can be confirmed safely.

BRIEF DESCRIPTION OF THE DRAWINGS The block diagram which illustrates the lightning surge test apparatus for coaxial ports which concerns on 1st Embodiment of this invention. The figure which illustrates the circuit for analog telephone ports of FIG. FIG. 2 is a diagram illustrating a circuit for the Ethernet port in FIG. 1. The figure which illustrates the circuit for power supply ports of FIG. The figure which illustrates the circuit for coaxial ports of the lightning surge test apparatus for coaxial ports which concerns on 2nd Embodiment of this invention. The figure which illustrates the circuit for coaxial ports different from the circuit for coaxial ports of FIG.

Embodiments according to the present invention will be described below with reference to the drawings.
[First Embodiment]
(Constitution)
FIG. 1 is a diagram illustrating a lightning surge test device (hereinafter also referred to as a test device) and a device under test 1 according to a first embodiment of the present invention.

  The device under test 1 includes a home communication device such as a home gateway, and includes a coaxial port 11, an analog telephone port 13, an Ethernet port 15, a power supply port 17, and a ground port 19.

  The coaxial port 11 is a port to which a first external device (hereinafter referred to as a counter device 70) such as a television receiver (not shown) is connected via the first coaxial cable 12. The analog telephone port 13 is a port to which an analog telephone device such as a telephone or FAX (hereinafter referred to as a counter device 30) is connected via an analog telephone cable 14. The Ethernet port 15 is a port to which a network device such as a router or a communication device such as a personal computer (hereinafter referred to as a counter device 40) is connected via the Ethernet cable 16. The power port 17 is a port to which a power source 50 such as a commercial power source or an adapter for supplying power to the device under test 1 via the power cable 18 is connected. The ground port 19 is a port that is grounded via the ground line 20. The analog telephone port 13, the Ethernet port 15, the power supply port 17, and the ground port 19 constitute an external connection port, and the opposing devices 30, 40 and the power supply device 50 constitute a second external device.

  The test apparatus includes a coaxial port circuit 2, an analog telephone port circuit 3, an Ethernet port circuit 4, a power supply port circuit 5, and a lightning surge generator 6.

  The lightning surge generator 6 includes an application terminal 61 (first terminal) and return terminals 62, 63, 64, and 65 (these are collectively referred to simply as “return terminal (second terminal)”). The lightning surge generator 6 has a changeover switch, and the changeover switch automatically switches the connection of a plurality of return terminals corresponding to the external connection port selected as the test target.

  The lightning surge generator 6 generates a plurality of types of lightning surges having different waveforms. The waveform of each lightning surge is specified for each external connection port to be tested. For example, the 10 / 700μs waveform specified by the international standard ITU-T K.44 and the 8 / 20μs (1.2 / 50μs) combination waveform specified by IEC61000-4-5 and IEEE Std C62.41.2 Four types of test waveforms are generated: 0.5 / 100 μs waveform and 10/1000 μs waveform. Each time the external connection port to be tested is selected, the lightning surge generator 6 selectively generates and outputs a test waveform corresponding to the selected external connection port.

  Further, the lightning surge generator 6 can automatically switch the application direction of the lightning surge. That is, in the lightning surge test, in addition to applying a forward lightning surge, a reverse lightning surge can also be applied. Here, the forward direction indicates a direction in which a lightning surge flows into the device under test 1 from the coaxial port 11. In the present embodiment, a case where a lightning surge in the forward direction is applied will be described.

  The coaxial port circuit 2 includes a first coaxial cable 12 connected to the coaxial port 11 and a termination resistor 21 that connects a central conductor and an external conductor of the first coaxial cable 12. . The outer conductor of the first coaxial cable 12 is connected to the application terminal 61 of the lightning surge generator 6.

  The terminating resistor 21 is set to a resistance value according to the characteristic impedance of the coaxial port 11 of the device under test 1. For example, if a television receiver is connected to the coaxial port 11, the resistance value of the termination resistor 21 is set to 75Ω, and the device under test 1 is connected to a coaxial cable having a characteristic impedance of 50Ω to the coaxial port. If so, the termination resistance is set to 50Ω.

  Further, the termination resistor 21 can perform a test when the outer conductor and the center conductor of the first coaxial cable 12 are short-circuited by setting the resistance value to 0Ω, and the resistance value is set to a sufficiently large value. Thus, it is possible to carry out a test when the outer conductor and the center conductor of the first coaxial cable 12 are insulated (open). At that time, as the terminating resistor 21, a variable resistor that can be arbitrarily variably set from 0Ω to infinity corresponding to an insulating state is used, or a circuit that switches a plurality of resistors having different resistance values by a changeover switch. Can be used.

  Note that the entire circuit of the coaxial port circuit 2 may be molded in order to prevent the terminal port 21 from jumping over and discharging. Further, the coaxial port circuit 2 may be directly connected to the coaxial port 11 without passing through the first coaxial cable 12. Further, the coaxial port circuit 2 may be provided with a switch capable of switching a plurality of termination resistors 21 having different resistance values.

  The analog telephone port circuit 3 is for applying a lightning surge only to the analog telephone port 13, and includes coupling circuits 31, 32 and a decoupling circuit 33 as shown in FIG. The coupling circuits 31 and 32 are composed of, for example, a surge protection device (SPD), and are connected between each of the two-wire analog telephone cable 14 and the lightning surge generator 6 so that the lightning surge is analog. It is applied only to the telephone port 13. The SPD is composed of, for example, gas discharge tubes (GDT), triode arresters, metal oxide varistors (MOV), capacitors, and the like.

  The decoupling circuit 33 is connected between the analog telephone cable 14 composed of the two wires and the opposing device 30 to prevent lightning surge from entering the opposing device 30. The circuit used for the decoupling circuit 33 is composed of, for example, an inductance, a filter, and an insulating transformer.

  The Ethernet port circuit 4 is for applying a lightning surge to the Ethernet port 15 via the Ethernet cable 16, for example, as shown in FIG. 3, the core wires 16-1,. Resistors 41-1,..., 41-n are individually connected between −n (where n = 8) and the return terminal 63 of the lightning surge generator 6. As the resistors 41-1,..., 41-n (n = 8), for example, resistors having a resistance value of 10Ω are used. However, in order to prevent a lightning surge from entering the counter device 40, the counter device 40 may be removed during the lightning surge application period, and the attachment operation may be checked after the application is completed. Further, as in FIG. 2, a decoupling circuit of an insulating transformer (such as a pulse transformer) may be inserted in front of the opposing device 40.

  The power port circuit 5 is for applying a lightning surge only to the power port 17 and includes coupling circuits 51 and 52 and a decoupling circuit 53 as shown in FIG. Similarly to the analog telephone port circuit 3 described above, the coupling circuits 51 and 52 are composed of, for example, a surge protection device (SPD), each of the power cable 18 having two wires, and the lightning surge generator 6. , So that a lightning surge is applied only to the power supply port 17. The SPD is composed of, for example, a metal oxide varistor (MOV).

  The decoupling circuit 53 is also composed of a surge protection device (SPD), and is connected between the power cable 18 composed of the two wires and the power supply 50 so that a lightning surge is applied to the power supply 50. To prevent. Similarly to the analog telephone port circuit 3 described above, the SPD used for the decoupling circuit 53 is also constituted by, for example, an inductance, a filter, and an insulating transformer.

  The analog telephone port circuit 3, Ethernet port circuit 4, power supply port circuit 5, and lightning surge generator 6 are configured in accordance with international standards ITU-T Recommendation K.44 and “Overvoltage Strength of Communication Devices”. Technical Requirements Ver. 2.1 Detailed information on Nippon Telegraph and Telephone Corporation (http://www.ntt.co.jp/ontime/img/pdf/oveTR189001ed2.1_20150410J.pdf) issued on April 1, 2015 Have been described.

  Further, the analog telephone port circuit 3, the Ethernet port circuit 4, the power supply port circuit 5, and the lightning surge generator 6 are not limited to the above configurations, and various configurations may be used. For example, the analog telephone port circuit 3 may have a circuit configuration using one analog telephone cable by short-circuiting the pair cable of the analog telephone cable 14. The same applies to the Ethernet port circuit 4 and the power port circuit 5 to which the Ethernet cable 16 and the power cable 18 are connected. In this case, since the opposite device cannot be connected, the opposite device is connected after the test is completed and the operation is confirmed.

(Operation)
The coaxial port lightning surge test apparatus configured as described above operates, for example, as follows.

  When conducting a lightning surge test between the coaxial port 11 and the analog telephone port 13 in the device under test 1, the coaxial port circuit 2 is connected between the application terminal 61 of the lightning surge generator 6 and the coaxial port 11. The analog telephone port circuit 3 is connected between the analog telephone port 13 and the return terminal 62 of the lightning surge generator 6. The lightning surge generator 6 generates a lightning surge and applies the lightning surge between the coaxial port 11 and the analog telephone port 13. Thereafter, by confirming the operation of the device under test 1, it is possible to clarify whether or not the device under test 1 has failed due to a lightning surge. The operation check is performed at the coaxial port 11 and the analog telephone port 13.

  When performing a lightning surge test between the coaxial port 11 and the Ethernet port 15 in the device under test 1, the coaxial port circuit 2 is connected between the application terminal 61 of the lightning surge generator 6 and the coaxial port 11, The Ethernet port circuit 4 is connected between the Ethernet port 15 and the return terminal 63 of the lightning surge generator 6. Then, a lightning surge is generated by the lightning surge generator 6 and a lightning surge is applied between the coaxial port 11 and the Ethernet port 15. At this time, the opposing device 40 is removed. Thereafter, by connecting the opposing device 40 to the Ethernet port 15 and confirming the operation of the device under test 1, it is possible to determine whether or not the device under test 1 has failed due to a lightning surge. The operation check is performed at the coaxial port 11 and the Ethernet port 15.

  When performing a lightning surge test between the coaxial port 11 and the power supply port 17 in the device under test 1, the coaxial port circuit 2 is connected between the application terminal 61 of the lightning surge generator 6 and the coaxial port 11, The power port circuit 5 is connected between the power port 17 and the return terminal 64 of the lightning surge generator 6. Then, the lightning surge generator 6 generates a lightning surge and applies the lightning surge between the coaxial port 11 and the power supply port 17. Thereafter, the presence or absence of failure of the device under test 1 due to lightning surge can be clarified. The operation check is performed at the coaxial port 11 and the power supply port 17.

  When performing a lightning surge test between the coaxial port 11 and the ground port 19 in the device under test 1, the coaxial port circuit 2 is connected between the application terminal 61 of the lightning surge generator 6 and the coaxial port 11, The ground port 19 and the return terminal 65 of the lightning surge generator 6 are connected. Then, a lightning surge is generated by the lightning surge generator 6, and a lightning surge is applied between the coaxial port 11 and the ground port 19. Thereafter, by grounding the ground port 19 and confirming the operation of the device under test 1, it is possible to clarify whether or not the device under test 1 has failed due to a lightning surge.

  The connection of the return terminal 63 of the lightning surge generator 6 to each of the external connection port circuits 3, 4, 5 described above is similarly caused under the control of the control circuit provided in the lightning surge generator 6. This is done by switching a changeover switch provided in the vessel 6. The lightning surge is also applied in conjunction with the switching operation of the changeover switch under the control of the control circuit corresponding to the external connection ports 13, 15 and 17 to be tested. Furthermore, the lightning surge generator 6 has a function of generating four types of lightning surge waveforms, and lightning surge waveforms corresponding to the respective external connection ports 13, 15 and 17 to be tested are selectively generated and applied. The That is, the lightning surge application operation corresponding to each of the external connection ports 13, 15, 17, 19 to be tested is automatically and sequentially performed under the control of the lightning surge generator 6.

(effect)
As described above in detail, in the first embodiment, a lightning surge test is performed between the coaxial port 11 of the device under test 1 and each of the other external connection ports 13, 15, 17, 19 of the device under test 1. Therefore, the coaxial port circuit 2 and the external connection ports 13, 15, 17, 19 are connected to the coaxial port circuit 2 and the external connection port circuits 3, 4, 5, respectively. A lightning surge is applied to the device under test 1 from the lightning surge generator 6 through the external connection port circuits 3, 4, 5.

  Accordingly, the coaxial port 11 is equivalent to a state in which a first external device using a coaxial cable such as a television receiver is connected by applying a lightning surge through the coaxial port circuit 2. The external connection ports 13, 15, 17, and 19 can be subjected to lightning surges through the external connection port circuits 3, 4, and 5, respectively. A lightning surge test with the coaxial port 11 can be performed without applying a lightning surge to the 30, 40 and the power supply device 50. That is, a lightning surge test between the coaxial port 11 and each of the other external connection ports 13, 15, 17, 19 that has not been considered so far can be accurately performed.

  In addition, since the lightning surge application operation corresponding to each of the external connection ports 13, 15, 17, and 19 to be tested is automatically and sequentially performed under the control of the lightning surge generator 6, the operation can be efficiently performed in a short time. The test can be performed reliably.

  That is, according to the above configuration, it is possible to apply a lightning surge to the device under test 1 using a test system suitable for the actual environment. Therefore, the lightning surge test between the coaxial port of the device under test 1 and other ports can be performed with good reproducibility without being influenced by the test environment (for example, the person, place, and device performing the test). .

[Second Embodiment]
(Constitution)
FIG. 5 is a diagram illustrating a coaxial port circuit 7 of a lightning surge test apparatus according to the second embodiment of the invention. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.

  The coaxial port circuit 7 includes a switch 72 that can switch the connection destination of the first coaxial cable 12 connected to the device under test 1 to either the lightning surge generator 6 or the opposing device 70. This is different from the coaxial port circuit 2 according to the embodiment.

  That is, the coaxial port circuit 7 includes a first coaxial cable 12 connected to the coaxial port 11, a second coaxial cable 71 connected to a counter device 70 such as a television receiver, a termination resistor 21, and the like. And a switch 72. The switch 72 is provided between the center conductor and the outer conductor of the first coaxial cable 12 and the center conductor and the outer conductor of the second coaxial cable 71, and the first coaxial cable 12 and the second coaxial cable. The connection with 71 is turned on and off. Moreover, when turning on the connection between the first coaxial cable 12 and the second coaxial cable 71, a switch 73 for disconnecting the connection with the lightning surge generator may be provided as illustrated in FIG. .

(Operation)
The coaxial port circuit 7 of the lightning surge test device configured as described above operates, for example, as follows.

  When the lightning surge test is performed, the coaxial port circuit 7 releases the switch 72 so that the lightning surge is not applied to the opposing device 70. On the other hand, when confirming the operation of the device under test 1 after the lightning surge test, the coaxial port circuit 7 turns on the switch 72 so that the device under test 1 and the opposing device 70 are connected. When the switch 73 is added, the coaxial port circuit 7 may operate in conjunction with the switch 72. For example, when the switch 73 is turned on, the switch 73 disconnects the connection with the lightning surge generator by turning the switch off.

(effect)
As described in detail above, in the second embodiment, by adding the switch 72 to the coaxial port circuit 7, the device connected to the coaxial port 11 of the device under test 1 can be switched. Specifically, when the lightning surge test is performed, the device under test 1 and the lightning surge generator 6 are connected by releasing the switch 72. When the operation of the device under test 1 is checked, the device under test 1 and the counter device 70 are connected by turning on the switch 72. Further, the connection with the lightning surge generator can be disconnected by adding the switch 73.

  Therefore, by using a configuration in which the lightning surge generator 6 and the counter device 70 connected to the coaxial port 11 of the device under test 1 can be switched by the switch 72, the operation of the device under test 1 after the lightning surge test is performed. Confirmation can be performed smoothly. Moreover, since the connection with the lightning surge generator is disconnected by providing the switch 73, the operation of the device under test 1 can be checked safely.

[Other Embodiments]
The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Further, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in each embodiment. Furthermore, you may combine suitably the component covering different embodiment.

  DESCRIPTION OF SYMBOLS 1 ... Test apparatus, 2, 7 ... Coaxial port circuit, 3 ... Analog telephone port circuit, 4 ... Ethernet port circuit, 5 ... Power supply port circuit, 6 ... Lightning surge generator, 11 ... coaxial port, 12 ... first coaxial cable, 13 ... analog telephone port, 14 ... analog telephone cable, 15 ... Ethernet port, 16 ... Ethernet cable, 16-1, 16-n core wire, 17 ... power port, 18 ... power cable, 19 ... ground port, 20 ... ground wire, 21 ... termination resistor, 30, 40, 70, opposite device, 31, 32, 51, 52, coupling circuit, 33, 53, decoupling circuit, 41-1, 41-n, resistor, 50. .Power supply device 61... Application terminal 62 63, 64, 65 ... return terminal, 71 ... second coaxial cable, 72, 73 ... switch.

To achieve the above object, according to a first aspect of the present invention, there is provided a device under test including a coaxial port to which a first external device is connected and at least one external connection port to which a second external device is connected. In order to perform a lightning surge test between the coaxial port and the external connection port of the device, a lightning surge generator that generates a lightning surge between the first terminal and the second terminal, and the lightning surge It is connected between the first terminal of the generator and the coaxial port, terminates the coaxial port corresponding to the first external device, and transmits the lightning surge to the coaxial through the outer conductor of the coaxial cable. A coaxial port circuit to be applied to the port, and a coupling circuit connected between the external connection port and the second terminal of the lightning surge generator, and limiting the application destination of the lightning surge to the external connection port For external connection port A road, a lightning surge generated from the lightning surge generator, and to be applied between the said coaxial port and the outside connection port through the circuit for that coaxial port circuit and the outside connection port It constitutes a lightning surge test device.

According to a fifth aspect of the present invention, the lightning surge generator further includes a circuit that alternately switches connection of the first terminal and the second terminal to the coaxial port circuit and the external connection port circuit. It is a thing.
According to a sixth aspect of the present invention, there is provided a thunder between the coaxial port and the external connection port of the device under test having a coaxial port to which the first external device is connected and at least one external connection port. In order to perform a surge test, a lightning surge generator that generates a lightning surge between the first terminal and the second terminal, and a connection between the first terminal of the lightning surge generator and the coaxial port A coaxial port circuit for terminating the coaxial port in correspondence with the first external device and applying the lightning surge to the coaxial port via an external conductor of the coaxial cable, and the external connection port Is a ground port, the second terminal of the lightning surge generator is connected to the ground port, and the lightning surge generated from the lightning surge generator is connected to the coaxial port via the coaxial port circuit. The ground It constitutes a lightning surge test apparatus that is applied between the over bets.

According to a seventh aspect of the present invention, there is provided a coaxial port circuit used in any one of the first to sixth aspects, the first coaxial cable connected to the coaxial port, and the first A second coaxial cable connected to the external device, an application terminal for a lightning surge generated by the lightning surge generator provided on the outer conductor of the first coaxial cable, and Termination means for terminating the first external device between the center conductor and the outer conductor, and between the first coaxial cable and the second coaxial cable during the lightning surge application period. And a switching means for connecting the first coaxial cable to the second coaxial cable after completion of the lightning surge application.

According to an eighth aspect of the present invention, there is provided a circuit for disconnecting the connection with the lightning surge generator when the coaxial port circuit in the seventh aspect connects the first coaxial cable to the second coaxial cable. The coaxial port circuit is further provided.

According to a fifth aspect of the present invention, the lightning surge generator further includes a circuit for alternately switching the connection of the first terminal and the second terminal to the coaxial port circuit and the external connection port circuit. Prepare. Therefore, the lightning surge application direction can be changed without changing the connection.
According to the sixth aspect of the present invention, it is possible to apply a lightning surge between the coaxial port and the ground port of the device under test using the lightning surge test device having the above configuration. For coaxial ports, by applying a lightning surge via the coaxial port circuit, a lightning surge test can be performed in a state equivalent to the state where external devices that use coaxial cables are connected. The lightning surge test between the ground and the ground port can be accurately performed. Therefore, a lightning surge test between the coaxial port and the ground port of the device under test can be performed in a test system that matches the actual environment, and depends on the test environment (for example, the person, place, and device performing the test). This can be done with good reproducibility.

According to a seventh aspect of the present invention, there is provided a circuit for a coaxial port of a lightning surge test apparatus, the first coaxial cable connected to the coaxial port and the second connected to the first external device. A coaxial cable, an application terminal for applying a lightning surge generated by the lightning surge generator, provided on an outer conductor of the first coaxial cable, a central conductor of the first coaxial cable, and the outer Terminating means for terminating the first external device between the conductor and the first coaxial cable and the second coaxial cable are separated from each other during the lightning surge application period, and the lightning A coaxial coupling circuit is provided that includes first switching means for connecting the first coaxial cable to the second coaxial cable after the application of surge. Since this coaxial coupling circuit can switch the lightning surge generator and the first external device connected to the coaxial port by the first switching means, the operation of the device under test after performing the lightning surge test Confirmation can be performed smoothly.

According to an eighth aspect of the present invention, when the coaxial port circuit connects the first coaxial cable to the second coaxial cable, the second switching means for disconnecting the connection with the lightning surge generator. Is further provided. Since the connection with the lightning surge generator is disconnected by the second switching means, the operation of the device under test can be confirmed safely.

Claims (7)

A lightning between the coaxial port and the external connection port of the device under test having a coaxial port to which the first external device is connected and at least one external connection port to which the second external device is connected A lightning surge test device for performing a surge test,
A lightning surge generator for generating a lightning surge between the first terminal and the second terminal;
The lightning surge generator is connected between the first terminal and the coaxial port, and terminates the coaxial port corresponding to the first external device, and the lightning surge is passed through the outer conductor of the coaxial cable. A coaxial port circuit to be applied to the coaxial port;
An external connection port circuit having a coupling circuit connected between the external connection port and the second terminal of the lightning surge generator and limiting the application destination of the lightning surge to the external connection port;
A lightning surge test apparatus, wherein a lightning surge generated from the lightning surge generator is applied between the coaxial port and the external connection port via the coaxial port circuit and the external connection port. When the device under test includes a plurality of external connection ports,
The plurality of external connection port circuits connected to each of the plurality of external connection ports and the second terminal of the lightning surge generator, and the plurality of external connection port circuits and the lightning surge generation The lightning surge test apparatus according to claim 1, further comprising a switch that selectively connects the second terminal of the detector. The lightning surge generator is
A means for selectively generating a lightning surge corresponding to an external connection port to be tested among the plurality of external connection ports from among a plurality of types of lightning surges set in advance in different waveforms,
In conjunction with the lightning surge selection operation, there is provided means for switching and controlling the switch so as to connect the external connection port to be tested to the second terminal of the lightning surge generator. The lightning surge test apparatus according to claim 2.   The lightning surge test apparatus according to any one of claims 1 to 3, wherein the coaxial port circuit further includes means for variably setting a resistance value for terminating the coaxial port.   The lightning surge generator further includes a circuit that alternately switches connection of the first terminal and the second terminal to the coaxial port circuit and the external connection port circuit. 4. The lightning surge test apparatus according to any one of 4 above. A circuit for a coaxial port used in the lightning surge test apparatus according to any one of claims 1 to 5,
A first coaxial cable connected to the coaxial port;
A second coaxial cable connected to the first external device;
An application terminal provided on an outer conductor of the first coaxial cable, for applying a lightning surge generated by the lightning surge generator;
Terminating means for terminating between the central conductor of the first coaxial cable and the outer conductor in correspondence with the first external device;
During the lightning surge application period, the first coaxial cable and the second coaxial cable are disconnected, and after the lightning surge application is completed, the first coaxial cable is connected to the second coaxial cable. A circuit for a coaxial port, comprising: a first switching means. A second switching means for disconnecting the connection with the lightning surge generator when connecting the first coaxial cable to the second coaxial cable;
The circuit for a coaxial port according to claim 6, further comprising: