JP3804560B2 - Repeater with auxiliary equipment for media testing - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a repeater having an auxiliary device for media testing. The repeater is installed on an ISDN digital subscriber line defined in TTC standard JT-G961 “Digital Transmission System on Metallic Local Line for ISDN Basic Route Access” for the purpose of extending the service coverage.
[0002]
[Prior art]
FIG. 1 is a configuration diagram of a conventional relay system. According to FIG. 1, the relay system has a line terminating device, a subscriber line 1, a repeater, a subscriber line 2, a power supply adapter (hereinafter referred to as “power supply ADP”) in the downstream direction (from the office building to the user's home). ) And network termination equipment. The signal system between the line terminator and the repeater and between the repeater and the network terminator follows the standard system.
[0003]
Below, each part of FIG. 1 is demonstrated. “Positive polarity” means that the voltage of the subscriber line composed of the L1 line and the L2 line is “L1 voltage”> “L2 voltage”, and “inverted polarity” means “L1 voltage” It indicates a state of “voltage” <“voltage of L2”.
[0004]
FIG. 2 is a configuration diagram of a conventional repeater. According to FIG. 2, the repeater includes a communication unit, a switching unit 1, a control unit 1, a storage battery 1, a voltage detection unit 1, and a voltage detection unit 2.
[0005]
The repeater operates with a DC power supply of 39 mA constant current from the line termination device. The switching unit 1 includes a switch 1 including a contact PREPcom1 and a contact PREPtst1, and a switch 2 including a contact PREPcom2 and a contact PREPstst2. The voltage detection unit 1 detects when a voltage of 20 V or more is applied between L1 and L2 by the Zener diodes DVz1 and DVz2 having a Zener voltage of 20 V, and transmits the logic “VREPcom = 1” to the control unit 1. If not detected, the logic “VREPcom = 0” is transmitted to the control unit 1. The voltage detection unit 2 detects when a voltage of 20 V or more is continuously applied between L1 and L2 by the Zener diodes DVz3 and DVz4 having a Zener voltage of 20 V for 10 seconds, and controls the logic “VREPtst = 1”. If not detected, the logic “VREPtst = 0” is transmitted to the control unit 1. The storage battery 1 is charged by a part of the DC power supply from the line termination device. The control unit 1 controls the switching unit 1 according to the logic received from each unit.
[0006]
FIG. 3 is a configuration diagram of the power feeding ADP. According to FIG. 3, the power supply ADP includes a power supply unit 1, a switching unit 2, a control unit 2, a test unit 1, and a voltage detection unit 3. The power supply ADP is operated by a commercial power supply AC100V.
[0007]
The power feeding unit 1 supplies a constant current of 39 mA (maximum voltage of 60 V) with a reverse polarity to the network termination device.
[0008]
The test unit 1 is configured as follows.
When a voltage of less than 20 V is applied between the subscriber line 2 inputs L1 and L2, the capacitor Ctst is charged.
When an inverted polarity voltage of 30 V or more is applied between the subscriber line 2 input portions L1 and L2, a current of 10 mA or more is passed through the resistor Rtst.
When a positive voltage of 20V or more is continuously applied between the subscriber line 2 input portions L1 and L2 for 8 seconds, the positive polarity detection portion 1 detects it and sets the logic “NVADPtst = 1” to the control portion 2. If not, the logic “NVADPtst = 0” is transmitted. If a current of 10 mA or more flows continuously through Rtst for 8 seconds, the reverse polarity current detection unit 1 detects it and the logic “RIADPtst = 1” ”Is transmitted to the control unit 2. Otherwise, the logic“ RIADPtst = 0 ”is transmitted.
[0009]
The voltage detection unit 3 detects when a voltage of 5 V or more is applied between the subscriber line input units L1 and L2 by the Zener diodes DVz4 and DVz5 having a Zener voltage of 5 V, and controls the logic “VADPcom = 1”. If it is not detected, the logic “VADOPcom = 0” is transmitted to the control unit 2.
[0010]
The switching unit 2 has contacts PADPcom1 and PADPtst1.
[0011]
4 to 12 show a medium test procedure of the conventional relay system.
[0012]
4 to 12, for simplification, each voltage detection unit shown in FIGS. 2 and 3 is represented as Open, and each current detection unit is represented as Short. The detection results of each detection unit are summarized in a square frame at the lower left in each figure. In the square frame, the underlined line indicates that the detected value has changed. In the figure, a thick solid line represents a portion to which a voltage of 20 V or higher is applied. When the direction is indicated by an arrow, a current of 10 mA or higher is assumed to flow. A thick dotted line shows the part to which the voltage of 5V-20V is applied. Moreover, when the contact of each switch is enclosed by the round frame, it shows that a contact switches in the following figure.
[0013]
According to FIG. 4, in the initial state, the station side connects a line terminator to the subscriber line 1.
[0014]
According to FIG. 5, the line terminator is switched to the medium tester during the medium test. At this time, the voltage of the subscriber line 1 becomes 30 V or more and less than 15 V, and the voltage detection unit 1 in the repeater detects it and transmits “VREPcom = 0” to the control unit 1. When receiving “VREPcom = 0”, the control unit 1 switches the switch 1 and the switch 2 of the switching unit 1 from the contacts PREPcom1 and PREcom2 to the PREPstst1 and PREPstst2, respectively. When the control unit 1 switches the switching unit 1, the repeater is operated by the storage battery 1 because it cannot receive DC power from the line termination device.
[0015]
According to FIG. 6, when the control unit 1 switches the switching unit 1, the voltage of the subscriber line 2 is changed from 0 V to 10 V to 15 V, and the voltage detection unit 2 detects this in the power feeding ADP and sends it to the control unit 2. VADPcom = 1 ”is transmitted. Upon receiving “VADPcom = 0”, the control unit 2 switches the switching unit 2 from the contact PADPcom1 to PADPtst1.
[0016]
According to FIG. 7, the media test is carried out in this state.
[0017]
According to FIG. 8, the insulation resistance test and the capacity test are conducted through the subscriber line 1 with a positive voltage source of less than 15V connected to the subscriber line 1 and through the subscriber line 1, the subscriber line 2 and the capacitor Ctst in the test section 1. Is implemented.
[0018]
According to FIG. 9, the conductor resistance test is performed by connecting the subscriber line 1 with a 39 mA constant current source (maximum voltage 60 V) with an inverted polarity continuously for a maximum of 5 seconds, the subscriber line 1, the subscriber line 2, and the test section. The test is performed through the internal resistance Rtst.
[0019]
At the time of switching back, the medium testing machine is switched to the line terminating device.
[0020]
According to FIG. 10, when the power supply circuit of the line termination device is connected to the subscriber line 1 with positive polarity, the voltage between L1 and L2 is 60V, and the positive polarity detection unit 1 of the power supply ADP is 8 seconds after connection. Detects this and transmits “NVADPtst = 1” to the control unit 2. 10 seconds after the connection of the line terminator, the voltage detector 2 of the repeater detects it and transmits “VREPtst = 1” to the controller 1. When the control unit 1 receives “VREPtst = 1”, the control unit 1 switches the switch 1 and the switch 2 of the switching unit 1 from the contacts PREPstst1 and PREPstst2 to the PREPcom1 and PREPcom2, respectively. At this time, since the DC voltage and the DC current between the subscriber line 2 inputs L1 and L2 of the power supply ADP are both zero, the positive polarity detection unit 1 of the power supply ADP transmits “NVADPtst = 0”. The control unit 2 receives “NVAPtst = 0” and “RLADPtst = 0” from the reverse polarity current detection unit 1 two seconds after the reception of “NVADPtst = 1”, so the switching unit 2 is connected to the PADPcom1 from the contact point PADPtst1. Switch back to. This returns to the initial state of FIG.
[0021]
According to FIG. 11, when the line termination device is connected to the subscriber line with the reverse polarity, a current of 10 mA or more flows, and the reverse polarity current detector 1 of the power feeding ADP detects it after 8 seconds from the connection, Transmit “RIADPtst = 1” to part 2. 10 seconds after the connection of the line terminator, the voltage detector 2 of the repeater detects it and transmits “VREPtst = 1” to the controller 1. When the control unit 1 receives “VREPtst = 1”, the control unit 1 switches the switch 1 and the switch 2 of the switching unit 1 from the contacts PREPstst1 and PREPstst2 to the PREPcom1 and PREPcom2, respectively. At this time, since both the DC voltage and the DC current between the subscriber line 2 input portions L1 and L2 of the power feeding ADP become zero, the reverse polarity current detection unit 1 of the power feeding ADP transmits “RIADPtst = 0”. Since the control unit 2 receives “RIADPtst = 0” and “NVADPtst = 0” from the positive polarity detection unit 1 after 2 seconds from the reception of “RIADPtst = 1”, the switching unit 2 is switched from the contact PADPtst1 to the PADPcom1. Cut back. This returns to the initial state of FIG.
[0022]
[Problems to be solved by the invention]
In the relay system of the prior art, the relay is operated by the storage battery 1 during the medium test. The storage battery 1 is charged by a part of the DC power supply from the line terminator, but most of the power from the line terminator is used for the operating power of the repeater. Takes time. Therefore, it is impossible to perform a medium test frequently and for a long time.
[0023]
Therefore, a method has been examined in which DC power is supplied from the power supply ADP of the subscriber's home device to the repeater and all the power from the power supply ADP is applied to the charging of the storage battery 1. However, since the power supply ADP is connected to the subscriber line 2 by the user, there is no guarantee that the polarity is positively connected. This means that there is no guarantee that the storage battery 1 will be charged.
[0024]
If the user accidentally reverses the polarity of the power supply ADP to the subscriber line, this relay system performs communication without any problem even if the polarity is incorrect during normal communication. Until then, the connection mistake of the power supply ADP is not noticed. However, even if the medium test is performed, the storage battery 1 of the repeater is not charged. Therefore, when the medium test is performed, there is no power for switching back, so the switching is never performed again. Therefore, it is impossible to perform the medium test normally.
[0025]
Even if the storage battery 1 has power, when the medium tester switches back to the line terminator, the operation of the power supply ADP differs depending on the polarity of the power supply circuit of the line terminator (voltage detection and inversion in the positive polarity) Therefore, when the power supply ADP is connected to the subscriber line 2 by mistake in polarity, these operations are not performed normally, so that switching back is impossible.
[0026]
On the other hand, a method of charging a storage battery regardless of the polarity of the power supply ADP by installing a full-wave rectifier circuit at the power supply ADP or the input part of the subscriber line 2 of the repeater has been studied. However, as shown in FIGS. 4 and 5, the polarity plays an important role during the medium test, and as described above, the polarity of the feeding ADP is important when switching back from the test. Therefore, the addition of a full-wave rectifier circuit that adjusts the polarity means that the media test cannot be performed accurately.
[0027]
The present invention has been made in view of such a problem. Regardless of the connection status (normal connection / reverse connection) of the power supply ADP to the subscriber line 2 by the user, the storage battery 1 in the relay is charged, and the medium A repeater having an auxiliary device for a medium test, which allows a test to be frequently performed for a long time, allows a medium test to be carried out normally, and allows switching back to the line termination device normally. The purpose is to provide.
[0028]
[Means for Solving the Problems]
According to the onset Ming, as defined in TTC standard JT-G961, the ISDN digital subscriber line composed of two-wire pair, and the line terminal, the network terminating device having a power supply adapter to the line terminator side In a repeater installed between and having a relay means and an auxiliary device , the auxiliary device is connected to the network termination device side of the relay means composed of a subscriber line and a pair of two wires from the network termination device. The relay means connected to the output line includes a storage battery charged by the power supply adapter, and a control unit that determines whether the subscriber line is in a communication state or a test state based on a voltage applied to the subscriber line. The auxiliary device is connected to the subscriber line from the auxiliary device and the line termination device, and when in communication, the auxiliary device is a full-wave rectifier having the subscriber line from the network termination device as an input and the input / output line of the relay means as an output. Operate and feed Regardless of the polarity of the voltage applied to the subscriber line of the adapter, the voltage is output with the polarity stored in the storage battery of the relay means, and the control unit determines the polarity of the voltage applied to the power supply adapter from the current flowing through the auxiliary device, and the test In the state, the control unit controls the auxiliary device based on the determined applied voltage polarity of the power supply adapter, and the auxiliary device receives the input / output line of the relay means as an input based on the control by the control unit, and from the network termination device. Operates as a full-wave rectifier with the subscriber line as an output, and performs output according to the applied voltage polarity of the power supply adapter regardless of the applied voltage polarity for the test from the line terminating device side to the subscriber line. Features.
[0029]
According to another embodiment of the present invention, the relay means includes a capacitor for preventing a DC voltage applied to the subscriber line from the line termination device side from being applied to the storage battery, and a line termination from the capacitor. A first detection unit that is disposed on the device side and detects a voltage applied to the subscriber line from the line termination device side; a communication unit that is disposed on the line termination device side from the capacitor and performs relay processing; Switching unit for inserting / withdrawing the detection unit, storage battery, capacitor and communication unit to / from the subscriber line, and a subscriber from the network termination device side arranged on the network termination device side from the capacitor, regardless of the state of the switching unit A second detection unit that detects a voltage applied to the line, and the control unit tests whether the subscriber line is in a communication state based on the voltages detected by the first detection unit and the second detection unit. It is determined whether it is in a communication state. The first detection unit, the storage battery, the capacitor, and the communication unit are controlled by inserting the first detection unit, the storage battery, the capacitor, and the communication unit into the subscriber line. Is also preferably disconnected from the subscriber line .
[0030]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0031]
FIG. 13 is a block diagram of a repeater according to the present invention. According to FIG. 13, the repeater includes a communication unit, a switching unit 1, a control unit 1, a storage battery 1, a voltage detection unit 1, a voltage detection unit 2, and an auxiliary device 1.
[0032]
The storage battery 1 is charged by DC power supply from the power supply ADP and used for the operation of the repeater.
[0033]
The voltage detection unit 1 detects when a voltage of 20 V or more is applied between L1 and L2 by the Zener diodes DVz1 and DVz2 having a Zener voltage of 20 V, and transmits the logic “VREPcom1 = 1” to the control unit 1. If not detected, the logic “VREPcom1 = 0” is transmitted to the control unit 1.
[0034]
The voltage detection unit 2 detects when a voltage of 20 V or more is applied between L1 and L2 by the Zener diodes DVz3 and DVz4 having a Zener voltage of 20 V, and transmits the logic “VREPcom2 = 1” to the control unit 1. If not detected, the logic “VREPcom2 = 0” is transmitted to the control unit 1.
[0035]
FIG. 14 is a block diagram of the auxiliary device 1 according to the present invention. According to FIG. 14, the auxiliary device 1 includes a positive current detection unit 1, an inversion polarity current detection unit 1, two switches including a contact PNcom and a contact PRtst, and two switches including a contact PNtst and a contact PRcom. And 8 diodes.
[0036]
The auxiliary device 1 has two modes “communication mode” and “test mode”. When the auxiliary device 1 is in the “communication mode”, it is assumed that the contact PNcom = ON and the contact PRtst = OFF, and the contact PNtst = OFF and the contact PRcom = ON. The “test mode” will be described in the following examples.
[0037]
The positive current detection unit 1 and the reverse polarity current detection unit 1 of the auxiliary device 1 operate as follows.
When the auxiliary device 1 is in the “communication mode”, “NLsw = 1” and “RLsw = 1” are transmitted to the control unit 1 when a current of 10 mA or more is detected for 60 ms.
When the auxiliary device 1 is in the “test mode”, “NLsw = 1” and “RLsw = 1” are transmitted to the control unit 1 when a current of 10 mA or more is detected for 10 seconds.
When a current of 10 mA or more cannot be detected for 60 ms regardless of the mode of the auxiliary device 1, “NLsw = 0” and “RLsw = 0” are transmitted to the control unit 1, respectively.
[0038]
FIG. 15 is a circuit configuration diagram of the power feeding ADP. The power supply ADP includes a power supply unit 1, a power supply unit 2, a switching unit 2, a control unit 2, a test unit 1, a current detection unit 1, and a current detection unit 2. The power supply ADP is operated by a commercial power supply AC100V.
[0039]
The power feeding unit 1 has a reverse polarity and connects a 39 mA constant current source (maximum voltage 60 V) to the network termination device.
[0040]
The power feeding unit 2 has a reverse polarity and connects a 60 V constant voltage source (maximum current 39 mA) to the subscriber line 2. At this time, it is referred to as “the feeding ADP is positively connected to the subscriber line 2”. The current detection unit 1 transmits “IADPcom = 1” to the control unit 2 when detecting a current of 10 mA or more for 60 ms, and transmits “IADPcom = 0” otherwise.
[0041]
The test unit 1 operates as follows.
When a voltage of less than 20 V is applied between the subscriber line 2 inputs L1 and L2, the capacitor Ctst is charged.
When an inverted polarity voltage of 30 V or more is applied between the subscriber line 2 input portions L1 and L2, a current of 10 mA or more flows through the resistor Rtst, and a current of 10 mA flows continuously through Rtst for 8 seconds. The detection unit 2 detects this and transmits the logic “IADPtst = 1” to the control unit 2, and otherwise transmits the logic “IADPtst = 0”. When a current flows through Rtst for an inverted polarity voltage of 30 V or more, it is called “the test unit 1 is positively connected to the subscriber line 2”.
[0042]
The switching unit 2 has contacts PADPcom1 and PADPtst1, and switches between “communication mode” and “test mode”.
[0043]
Below, the operation | movement procedure of the auxiliary | assistant apparatus 1 of this invention is demonstrated.
[0044]
Assume that the auxiliary device 1 in the initial state is in the “communication mode”.
[0045]
According to FIG. 16, when the power supply ADP is positively connected to the subscriber line 2, the positive current detection unit 1 transmits “NLsw = 1” to the control unit 1. When the power supply ADP is reversely connected to the subscriber line 2, the reverse polarity current detection unit 1 transmits “RLsw = 1” to the control unit 1. When the control unit 1 receives “reverse polarity current detection = ON”, it sets the flag value “F = 1”.
[0046]
FIG. 16 shows the configuration of the auxiliary device 1 in the communication mode, and the relationship between the connection state (forward / reverse connection) of the power feeding ADP and the charging polarity of the storage battery 1. It is understood that the storage device 1 is charged by the auxiliary device 1 regardless of the connection status (forward connection / reverse connection) of the power feeding ADP.
[0047]
Next, the medium test will be described.
[0048]
The auxiliary device 1 transitions from the communication mode to the test mode when the control unit 1 switches the switching unit 1. In the case of the flag value “F = 0”, the auxiliary device 1 sets the contact PNcom = ON and the contact PRtst = OFF, and sets the contact PNtst = ON and the contact PRcom = OFF when transitioning to the test mode. Further, when the flag value “F = 1”, the auxiliary device 1 sets the contact point PNcom = OFF and the contact point PRtst = ON, and sets the contact point PNtst = OFF and the contact point PRcom = ON when transitioning to the test mode.
[0049]
17 and 18 show the configuration of the auxiliary device 1 in the test mode, the connection status of the power supply ADP (forward / reverse connection), the polarity applied to the subscriber line during the medium test, and the connection of the test unit 1. The relationship with the situation (forward / reverse connection) is shown. It is understood that the test is performed by the auxiliary device 1 with the positive connection with respect to the test unit 1 regardless of the connection state (forward connection / reverse connection) of the power supply ADP.
[0050]
19 and 20 show the configuration of the auxiliary device 1 in the test mode, the connection status (forward / reverse connection) of the power supply ADP, and the line termination device power supply circuit at the time of switching back from the medium tester to the line termination device. The relationship between a polarity and the connection condition of the test part 1 is shown. It is understood that the test unit 1 is positively connected to the subscriber line 2 by the auxiliary device 1 regardless of the connection status (forward / reverse connection) of the power supply ADP and the polarity of the line termination device power supply circuit at the time of switching back. The
[0051]
21 to 32 are media test procedures of the present invention. The format of the figure is the same as in the prior art.
[0052]
According to FIG. 21, since the connection polarity of the power supply ADP does not affect the procedure by the auxiliary device 1 as described above, it is assumed here that the power supply ADP is positively connected.
[0053]
According to FIG. 22, the line terminator is switched to the medium tester during the medium test. At this time, the voltage of the subscriber line 1 becomes 30 V or more and less than 15 V, and the voltage detection unit 1 in the repeater detects it and transmits “VREPcom1 = 0” to the control unit 1.
[0054]
According to FIG. 23, when receiving “VREPcom1 = 0”, the control unit 1 switches the switch 1 of the switching unit 1 from the contact PREPcom1 to PREPtst1, disconnects the switch 2 from the PREPcom2, and does not connect to either PREPcom2 or PREPstst2. At this time, the current detection unit 1 of the power feeding ADP transmits “IADPcom = 0” to the control unit 2.
[0055]
According to FIG. 24, when receiving “IADPcom = 0”, the control unit 2 switches the switching unit 2 from the contact PADPcom to PADPtst and connects the test unit 1 to the subscriber line 2. At this time, the voltage detection circuit 2 of the repeater transmits “VREPcom2 = 0” to the control unit 1.
[0056]
According to FIG. 25, when the control unit 1 receives “VREPcom2 = 0”, it connects the switch 2 to the contact PREPstst2. The media test is performed in this state.
[0057]
According to FIG. 26, in the insulation resistance test and the capacity test, a constant voltage source having a positive polarity of less than 15 V is connected to the subscriber line 1, and the test is conducted through the subscriber line 1, the subscriber line 2, and the capacitor Ctst in the test unit 1. Is implemented.
[0058]
According to FIG. 27, in the conductor resistance test, a 39 mA constant current source (maximum voltage 60V) with a reverse polarity is continuously connected to the subscriber line 1 for a maximum of 5 seconds, and the subscriber line 1, the subscriber line 2, and the test section The test is performed through the internal resistance Rtst.
[0059]
Next, switching back will be described.
[0060]
At the time of switching back, the medium testing machine is switched to the line terminating device. At this time, a current of 10 mA or more flows through the subscriber line. Eight seconds after the connection to the line termination device, the current detection unit 1 of the power feeding ADP transmits “IADP = 1” to the control unit 2. FIG. 28 shows a case of a line termination device power supply circuit positive connection. FIG. 29 shows a case of line termination device power supply circuit reverse polarity connection.
[0061]
When receiving “IADP = 1”, the control unit 2 switches the switching unit 2 from the contact PADPtst to PADPcom. Two seconds later, when the line terminating device power supply circuit is positively connected to the subscriber line 1, the positive current detection circuit 1 of the auxiliary device 1 transmits “NLsw = 1” to the control unit 1, and When the termination device power supply circuit is connected to the subscriber line 1 with the reverse polarity, the reverse polarity current detection circuit 1 of the auxiliary device 1 transmits “RLsw = 1” to the control unit 1. FIG. 30 shows a case of a line termination device feed circuit positive polarity connection. FIG. 31 shows a case of line termination device power supply circuit reverse polarity connection.
[0062]
According to FIG. 32, when “NLsw = 1” or “RLsw = 1” is received, the control unit 1 switches the contact PREPstst1 of the switch 1 and the contact PREPstst2 of the switch 2 to the contacts PREPcom1 and PREPcom2, respectively. This completes the switchback.
[0063]
【The invention's effect】
As described above in detail, according to the present invention, regardless of the connection status (forward connection / reverse connection) of the power supply ADP to the subscriber line 2 by the user, the storage battery 1 in the repeater is reliably charged, The medium test can be frequently performed for a long time, the medium test can be normally performed, and the switch back to the line terminating device can be normally performed.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a conventional relay system.
FIG. 2 is a circuit configuration diagram of a conventional repeater.
FIG. 3 is a circuit configuration diagram of a power feeding ADP.
FIG. 4 is a first state of a medium test switching procedure in a conventional relay system.
FIG. 5 shows a second state of the medium test switching procedure in the conventional relay system.
FIG. 6 is a third state of the medium test switching procedure in the conventional relay system.
FIG. 7 is a fourth state of the medium test switching procedure in the conventional relay system.
FIG. 8 is a fifth state of a medium test switching procedure in the conventional relay system.
FIG. 9 is a sixth state of the medium test switching procedure in the conventional relay system.
FIG. 10 shows a seventh state of the medium test switching procedure in the conventional relay system.
FIG. 11 shows an eighth state of the medium test switching procedure in the conventional relay system.
FIG. 12 shows a ninth state of the medium test switching procedure in the conventional relay system.
FIG. 13 is a block diagram of a repeater according to the present invention.
FIG. 14 is a circuit configuration diagram of an auxiliary device for a repeater according to the present invention.
FIG. 15 is a circuit configuration diagram of a power feeding ADP.
FIG. 16 is an explanatory diagram showing the relationship between the connection state of the power feeding ADP and the charging polarity of the storage battery in the communication mode.
FIG. 17 is a first explanatory diagram illustrating a relationship between a connection state of a power feeding ADP, a polarity applied to a subscriber line during a medium test, and a connection state of a test unit 1 in a test mode.
FIG. 18 is a second explanatory diagram showing the relationship between the connection status of the power supply ADP, the polarity applied to the subscriber line during the medium test, and the connection status of the test unit 1 in the test mode.
FIG. 19 is a first diagram illustrating the relationship between the connection status of the power supply ADP, the polarity of the line termination device power supply circuit when switching back from the medium tester to the line termination device, and the connection status of the test unit 1 in the test mode; It is explanatory drawing.
FIG. 20 is a second diagram illustrating the relationship between the connection status of the power supply ADP, the polarity of the line termination device power supply circuit when switching back from the medium tester to the line termination device, and the connection status of the test unit 1 in the test mode; It is explanatory drawing.
FIG. 21 is a first state of a medium test switching procedure in the relay system of the present invention.
FIG. 22 is a second state of the medium test switching procedure in the relay system of the present invention.
FIG. 23 is a third state of the medium test switching procedure in the relay system of the present invention.
FIG. 24 is a fourth state of the media test switching procedure in the relay system of the present invention.
FIG. 25 is a fifth state of the medium test switching procedure in the relay system of the present invention;
FIG. 26 shows a sixth state of the medium test switching procedure in the relay system of the present invention.
FIG. 27 is a seventh state of the medium test switching procedure in the relay system of the present invention;
FIG. 28 is an eighth state of the medium test switching procedure in the relay system of the present invention.
FIG. 29 is a ninth state of the medium test switching procedure in the relay system of the present invention.
FIG. 30 is a tenth state of the medium test switching procedure in the relay system of the present invention;
FIG. 31 is an eleventh state of the medium test switching procedure in the relay system of the present invention;
FIG. 32 is a twelfth state of the medium test switching procedure in the relay system of the present invention.

Claims (2)

A relay means installed between a line terminating device and a network terminating device having a power supply adapter on the line terminating device side of an ISDN digital subscriber line composed of a pair of two wires stipulated in TTC standard JT-G961 And a repeater comprising an auxiliary device ,
The auxiliary device is connected to the input / output line from the network termination device to the network termination device side of the subscriber line and the two-wire pair of relay means,
The relay means includes a storage battery stored by the power supply adapter, and a control unit that determines whether the subscriber line is in a communication state or a test state based on a voltage applied to the subscriber line, and the auxiliary device and the line termination Connected to the subscriber line from the device,
During communication
The auxiliary device operates as a full-wave rectifier with the subscriber line from the network termination device as input and the input / output line of the relay means as output, and relays regardless of the polarity of the voltage applied to the subscriber line of the power supply adapter. Output the voltage with the polarity stored in the storage battery of the means,
The control unit determines the applied voltage polarity of the power supply adapter from the current flowing through the auxiliary device,
During the test state
The control unit controls the auxiliary device based on the determined applied voltage polarity of the power supply adapter,
Based on the control by the control unit, the auxiliary device operates as a full-wave rectifier having the input / output line of the relay means as an input and the subscriber line from the network terminator as an output, and the subscriber line from the line terminator side. Regardless of the applied voltage polarity for the test, the output according to the applied voltage polarity of the power adapter must be performed.
A repeater characterized by Relay means
A capacitor that prevents the DC voltage applied to the subscriber line from the line terminating device side from being applied to the storage battery;
A first detector that is disposed closer to the line termination device than the capacitor and detects a voltage applied to the subscriber line from the line termination device side;
A communication unit that is arranged on the line termination device side from the capacitor and performs relay processing;
A first detection unit, a storage battery, a capacitor, and a communication unit, a switching unit for inserting and removing from the subscriber line,
A second detection unit that is disposed on the network termination device side from the capacitor and detects a voltage applied to the subscriber line from the network termination device side regardless of the state of the switching unit;
Have
The control unit determines whether the subscriber line is in a communication state or a test state based on the voltage detected by the first detection unit and the second detection unit, and controls the switching unit in the communication state. The first detection unit, the storage battery, the capacitor and the communication unit are inserted into the subscriber line, and in the test state, the switching unit is controlled to disconnect the first detection unit, the storage battery, the capacitor and the communication unit from the subscriber line. thing,
The repeater according to claim 1.

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