KR100771225B1 - System for Testing Service Status in PSTN Network - Google Patents

Abstract

The present invention relates to a service state test system in a PSTN network, the system according to the present invention comprising: a test control device connected to a telephone exchange system; And a test terminal device connected to an exchange system to be tested, wherein the test control device connects a call with the test terminal device to receive a first test code from the test terminal device, and the received first test code is The transmission state of the switching system to be tested is tested by determining whether the first test code matches the preset first test code, and after the transmission state test is completed, the test terminal device connects a call with the test control device to control the test. The reception state of the test exchange system is tested by receiving a second test code from the device and determining whether the received second test code matches a preset test code.

Exchanger, test, PSTN

Description

 System for Testing Service Status in PSTN Network

1 is a block diagram showing the configuration of a service state test system in a PSTN network according to an embodiment of the present invention.

2 is a flowchart illustrating the overall flow of a service state test method in a PSTN network according to a first embodiment of the present invention.

3 is a flowchart illustrating the overall flow of a service state test method in a PSTN network according to a second embodiment of the present invention;

4 is a block diagram showing a detailed configuration of a test control device according to an embodiment of the present invention.

5 is a block diagram showing a detailed configuration of a test terminal device according to a first embodiment of the present invention.

6 is a block diagram showing a detailed configuration of a test terminal device according to a second embodiment of the present invention.

7 is a circuit diagram showing a detailed configuration of a constant voltage circuit according to a preferred embodiment of the present invention.

The present invention relates to a service state test system in a public switched telephone network (PSTN) network, and more particularly, to a system for effectively testing a state of a switching or transmission system.

The PSTN network is a network that provides voice telephony or data exchange service to an unspecified number of subscribers through an exchange office, and services are provided using a plurality of exchanges. The service state in the PSTN network is mainly tested using the exchange.

In the related art, a method of transmitting a test signal to the exchange and testing the state of the exchange using the loopback signal transmitted according to the difference in impedance has been mainly used. However, this method is effective in checking the line condition between the telephone company and the exchange. However, even if the line state is good, it is possible to check whether the terminal connected to the exchange can be provided with stable service due to problems in the exchange. There was no problem.

In addition, a method of monitoring a switch's status information by providing a chip for checking the status of the switch and providing an abnormal status occurrence information to a telephone station when an abnormality occurs is used. However, this method also has a problem that can not detect all the causes of various communication failures.

Therefore, in order to check the service status of the exchange for the unmanned station, there was no choice but to check the status of sending and receiving directly by sending a separate manpower. Therefore, the cost and time loss caused by this is huge. There is a need for a system that can be tested.

In order to solve the problems of the prior art as described above, the present invention provides a service state test system in a PSTN network that can effectively detect a service abnormality condition caused by various failure factors by transmitting and receiving a test signal between the control device and the terminal. I would like to suggest.

Another object of the present invention is to propose a system that can effectively test the service status in the PSTN network automatically without sending a separate personnel for the service status test.

In order to achieve the above object, according to an aspect of the present invention, the test control device connected to the telephone exchange system; And a test terminal device connected to an exchange system to be tested, wherein the test control device connects a call with the test terminal device to receive a first test code from the test terminal device, and the received first test code is The transmission state of the switching system to be tested is tested by determining whether the first test code matches the preset first test code, and after the transmission state test is completed, the test terminal device connects a call with the test control device to control the test. A service state test system in a PSTN network is provided for receiving a second test code from a device and determining whether the received second test code matches a preset test code to test a reception state of a test switching system.

Preferably, the first test code and the second test code transmitted by the test control device and the test terminal device are DTMF codes.

After the test for the first test code is completed, the test terminal device transmits a call completion code to the test control device to release the call connection with the test control device, and calls the test number of the test control device to test Resume the call connection with the control device.

The test terminal device may receive a DTMF code corresponding to the phone number of the test control device from the test control device to recognize the phone number of the test control device.

In contrast, when the test control device attempts to connect a call, the test terminal device may recognize a telephone number of the test control device by using a caller ID recognition function.

The test terminal device preferably operates with a torque current provided from an exchange system as a power source.

The test terminal device includes a constant voltage circuit, wherein the constant voltage circuit is a processor of the test terminal device that has a predetermined low power so that the switching system can continuously recognize the state of the test terminal device as the hook-on state when the hook-on state is in the hook-on state. And, when in the hook-off state, the torque current of the switching system is used to power other circuits of the test terminal device.

According to another aspect of the present invention, a test control device for use in a test system comprising a test control device connected to the switching system of the telephone station and a test terminal device connected to the switching system to be tested for status testing in the PSTN network, A line interface connected with the telephone line; A DTMF receiver which dials the test terminal device and analyzes a first test code transmitted from the test terminal device when a call is connected; A DTMF transmitter for generating a second preset test code and transmitting the preset test code to the test terminal device when the test terminal device makes a call; A processor that controls the overall operation of a test control device and determines whether the received first test code matches a preset first test code to test a transmission state of a switching system to be tested; According to the control of the processor, a test control device including a hook switch for performing a hook-off or a hook-on operation is provided.

According to still another aspect of the present invention, there is provided a test terminal device for a test system including a test control device connected to an exchange system of a telephone station and a test terminal device connected to an exchange system to be tested for a state test in a PSTN network. A line interface connected to the telephone line; A DTMF transmitter which, when the test control device makes a call and connects a call, generates a first test code which is set in advance and transmits it to the test control device; A DTMF receiver which dials the test control device and analyzes a second test code transmitted from the test control device when a call is connected; A low power processor that controls the overall operation of a test terminal device, and determines whether the received second test code matches a preset second test code to test a reception state of a switching system to be tested; A hook switch for performing a hook-off or a hook-on operation according to the control of the processor, wherein the test releases the call connection after the test for the first test code is completed and attempts to connect the call to the test control device. A terminal device is provided.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the service state test system and method in a PSTN network according to the present invention.

1 is a block diagram illustrating a configuration of a service state test system in a PSTN network according to an exemplary embodiment of the present invention.

Referring to FIG. 1, a service state test system in a PSTN network according to an embodiment of the present invention includes a test control device 100 and an exchange system 102 of a telephone station, an exchange system 104 and a tester terminal device of an unmanned station. 106.

The present invention proposes a system for effectively testing a service state of an unmanned station without a separate test personnel assigned. As described above, the test in the conventional unmanned station is performed by using a loopback signal or the like transmitted from the exchange, but this method can test the line condition between the telephone station and the unmanned station, but the service is actually performed by the unmanned station. It was difficult to test whether the receiving terminal was able to make a normal call, and there was a problem that the actual test had to be made by sending a separate manpower.

The present invention proposes a method that can test the state of the exchange system without dispatching a separate manpower through the test control device 100 installed in the telephone station and the test terminal device 106 installed in the unmanned national company.

In FIG. 1, the test control device 100 is connected with a telephone exchange system 102. The switching system 102 here may be a general switch and may comprise all the switching means necessary for telephony communication.

The test terminal device 106 is also connected to the unmanned station switching system 104 and tests the service state of the unmanned station switching system through communication with the test control device. The network connecting the switching systems may be a general public switched telephone network (PSTN) network and may include an integrated services digital network (ISDN) network for data communication.

The test control device 100 makes a call to the terminal device of the unmanned station, and thus a ring signal is transmitted to the test terminal device, and receives a preset test signal from the test terminal device to make a call from the telephone station to the terminal connected to the unmanned station. Test the service status when hanging.

The test control device 100 makes a call like a normal telephone to connect a call with the test terminal device 106, and the test terminal device transmits a test signal while the call is connected. According to a preferred embodiment of the present invention, the test signal transmitted from the test terminal device 106 is a dual tone multi frequency (DTMF) signal.

After the test control device 100 calls the test terminal device 106 and tests the transmission state, the test terminal device 106 calls the test control device 100 to test the reception state. .

According to the first embodiment of the present invention, the test control device 100 provides its telephone number information to the test terminal device 106 during the transmission state test, and the test terminal device 106 transmits the corresponding phone number to the memory. After storing the transmission state test, dial the test control device 100 to connect the call.

According to the second embodiment of the present invention, the test terminal device 106 is provided with a caller ID recognition device, and stores a telephone number recognized by the caller ID recognition device in a memory and then ends the transmission state test. Call the test control device 100 and connect the call.

The test terminal apparatus 106 recognizes the telephone number of the test control apparatus according to the method of the first embodiment or the second embodiment described above, and then transmits a DTMF signal corresponding to the telephone number to the switching system to test terminal apparatus 106. ), And the test control device 100 tests the reception state by transmitting a preset test signal to the test terminal device 106 after the call is connected. It is preferable that the test signal transmitted from the test control device 100 to the test terminal device 106 is also a DTMF signal.

According to a preferred embodiment of the present invention, it is preferable that the test terminal device 106 operates only with a talk battery provided through an exchange without requiring a separate power source.

As described with reference to FIG. 1, the present invention directly connects a call by a test control device and a test terminal device, and checks a state through a test signal for both a transmission state and a reception state.

In the conventional case, the abnormal state was checked by a test algorithm provided in the loopback or the exchange. However, this method has a problem in that it is not possible to detect all the various failures occurring in the communication network. It automatically detects the transmission / reception status through the test control device / test terminal device set, which enables stable testing compared to the conventional method without sending a separate manpower to the unmanned station.

2 is a flowchart illustrating the overall flow of a service state test method in a PSTN network according to a first embodiment of the present invention.

Referring to Fig. 2, first, the test control apparatus of the telephone station makes a call to a test terminal apparatus for testing a state, and thus a ring signal is transmitted to the test terminal apparatus (step 200). The test control device may make a call to a specific test control device by an operator's operation, or may make a call automatically according to a preset test algorithm. According to a preferred embodiment of the present invention, the test control device may be connected to the operator's computer via a LAN or other network, and the operator may control the operation of the test control device through the computer.

The test terminal apparatus detects a ring signal transmitted through the switching system (step 202), and performs a hook off operation to answer a call when a ring signal is detected for a preset number of times (step 204). The call between the test control device and the test terminal device is connected by the hook-off operation of the test terminal device.

When the call with the test control device is connected, the test terminal device transmits a DTMF code corresponding to the preset test signal to the test control device (step 206). Since the device for connecting the call to the test terminal device will be a test control device, the test terminal device may be set to immediately transmit a test signal upon call connection without going through a separate determination process. Of course, it will be apparent to those skilled in the art that the test signal may be transmitted after determining whether the call is connected to the normal test control device. The test DTMF code may be set variously, for example, 1-3-4-7-8-9.

The test control device that receives the DTMF code from the test terminal device determines whether the DTMF code matches the preset DTMF code (step 208). If the received DTMF code does not match the preset DTMF code, the test control device determines that there is an error in the unmanned station to which the test terminal device is connected, and outputs an alarm signal or an alarm message to the operator (not shown).

If the received DTMF code and the preset DTMF code match, the test control device determines that the transmission service state is normal, and transmits the telephone number information set in the test control device to the test terminal device (step 212). As described above, after the test control device makes a call and checks the state, the test terminal device calls the test control device again to check the service state. In this case, when a plurality of test control devices are operated, the test terminal device Since the test control device to be called cannot be identified, the test control device sends the phone number information immediately after the status test. The phone number information may also be transmitted to the test terminal device in the form of a DTMF code.

The test terminal device having received the telephone number information of the test control device stores the telephone number in the memory and transmits a call completion code indicating the end of the transmission state test. The call completion code may be variously set, for example, "#", and the call completion code is also transmitted to the test control device in the form of DTMF.

After the call completion code is transmitted to the test control device, the test terminal device and the test control device hang up the phone (hook-on) (step 214).

After the call is terminated, the test terminal device makes a call to the test control device using the received telephone number information after a preset waiting time, and thus a ring signal transmitted by the switching system is transmitted to the test control device. (Step 216). If a call is not received from the test terminal device even after the preset waiting time has elapsed, the test control device determines that there is an error in the corresponding switching system and provides an alarm signal or an alarm message to the operator.

When the ring signal is transmitted, the test control device detects the ring signal and performs a hook off operation to answer a call when the ring signal is detected for a preset number of times (step 218).

When a call is connected between the test control device and the test terminal device by the hook-off of the test control device, the test control device generates and transmits a DTMF code corresponding to the preset test signal to the test terminal device (step 220). Since the device that attempts to connect the call to the test control device after the preset waiting time has passed, the test control device may be configured to transmit the DTMF code immediately after the call is connected without performing a separate determination process. However, it will be apparent to those skilled in the art that the caller may be configured to transmit the DTMF code after determining whether the call connection is made from the correct test terminal device using the calling party identification function.

The test terminal device determines whether the DTMF code transmitted from the test control device matches the preset DTMF code (step 222). As a result of the DTMF decryption, when the received DTMF code matches the preset DTMF code, the test terminal device determines that the service state is normal and transmits the preset call completion code to the control device (step 224).

However, if the received DTMF code does not match the preset DTMF code, the test terminal device determines that the service state is not normal. The operation of the test terminal device when the service state is not normal may be variously set.

For example, the test terminal device does not transmit a preset call completion code when the service state is not normal, and the test control device notifies that the service state is abnormal when the call completion code is not received for a predetermined time. It may provide an alarm signal or an alarm message.

Alternatively, the test terminal device may transmit a preset service abnormal status code to the test control device.

When the normal call completion code is received from the test terminal device, the test control device determines that the service state is normal, and the test terminal device and the test control device hang up the call (step 224).

3 is a flowchart illustrating the overall flow of a service state test method in a PSTN network according to a second embodiment of the present invention.

As described above, the second embodiment is an embodiment in which the telephone number of the test control device is recognized by the caller ID recognition device of the test terminal without directly transmitting the telephone number of the test control device.

Compared with FIG. 2, FIG. 3 further includes a step in which the test control device calls the test terminal device and recognizes the telephone number of the calling caller when the ring signal is transmitted to the test terminal device (step 304). .

Thus, step 210, in which the test control device transmits its own phone number in FIG. 2, is omitted in FIG.

3 is the same as the operation of FIG. 2 except for the difference described above, and thus a detailed description thereof will be omitted.

4 is a block diagram showing a detailed configuration of a test control device according to an embodiment of the present invention.

Referring to FIG. 4, a test control device according to an embodiment of the present invention includes a line interface 400, a DTMF receiver 402, a DTMF transmitter 404, a ring detector 406, a processor 408, and a LAN connection unit ( 410 may include a hook switch 412 and a memory 414.

In FIG. 4, the line interface 400 is connected to the switching system via a telephone line and transmits a signal to the switching system, and serves to transmit a signal transmitted from the switching system to the corresponding device. For example, the line interface 400 transmits a DTMF signal or a test DTMF signal for connecting a call with a test terminal device to a switching system, and receives a test DTMF signal or a ring signal from the switching system to receive a DTMF receiver 402. Or a ring detector 406 or the like. The line interface may be implemented in various types of circuits including analog and digital, and since the circuit is already known, a detailed circuit configuration of the line interface will be omitted.

The DTMF receiver 402 functions to analyze the DTMF signal transmitted through the line interface 400. The DTMF receiver 402 analyzes the frequency of the transmitted DTMF signal to determine which number the DTMF signal corresponds to, and provides the analysis result to the processor 408 in the form of an electrical signal. The DTMF signal received by the DTMF receiver 402 may include a test DTMF code and a call completion code transmitted by the test terminal device. The DTMF receiver may be implemented in the form of a chip, or may use a commercially available DTMF receiver chip.

The DTMF transmitter 404 functions to generate and transmit a DTMF signal while a call is connected to the test terminal device. After receiving the test DTMF code from the test terminal device, the DTMF transmitter 404 generates a DTMF code corresponding to the telephone number of the test control device and transmits it to the test terminal device. In this case, the phone number information of the test control device may be provided from the processor 408, and a DTMF code corresponding to the provided phone number is generated. Of course, according to the second embodiment, the DTMF transmitter will not perform the task of transmitting the DTMF code corresponding to the telephone number. In addition, when the test terminal device makes a call and the call is connected, the DTMF transmitter generates a preset test DTMF code and transmits it to the test terminal device. The preset test number may also be provided from the processor 408.

The ring detector 406 functions to detect ring signals transmitted from the switching system. When a ring signal is received more than a preset number of times, the ring detector 406 provides the processor 408 with information that the ring signal has been detected, and the processor 408 has a hook switch 412 for hook-off operation. Control to perform. The hook switch 412 performs a hook-on or hook-off operation under the control of the processor 408. The hook switch 412 maintains the hook-off state during the test, and the hook-on state when the test switch is not in the test state.

The processor 408 controls the overall operation of the test control device and analyzes the received signal to determine the state of the unmanned exchange system. The processor 408 receives the code information analyzed by the DTMF receiver 402 to determine whether it matches the preset DTMF code, and accordingly, determines the exchange state of the unmanned station. In addition, the processor controls the operation of each module of the test control device to perform the operation corresponding to the event when a predetermined event occurs. For example, when a ring signal is detected, the processor controls the hook switch 412 to change the state of the test terminal device to the hook-off state, and controls the DTMF transmitter to transmit a preset test DTMF code.

The memory 414 may store data related to a test and a program related to an operating algorithm of the processor. As memory, various types of memory such as RAM, ROM, EEPROM, and flash memory may be used.

The LAN connection unit 410 performs a LAN connection when the operator's terminal and the test control device are connected through the LAN. A normal LAN card could be used as the LAN connection. Of course, the operator terminal and the test control device do not necessarily need to be connected via a LAN, but may be directly connected by using a serial port.

5 is a block diagram showing a detailed configuration of a test terminal device according to a first embodiment of the present invention.

Referring to FIG. 5, the test terminal device according to the first embodiment of the present invention may include a protection circuit 500, a line interface 502, a reception signal amplifier 504, a DTMF receiver 506, a DTMF transmitter 508, Transmit signal amplifier 510, constant voltage circuit 512, hook switch 514, ring detector 516, and low power processor 518.

In FIG. 5, the protection circuit 500 functions to protect the test terminal device from high voltage when an impact voltage due to lightning or other factors is applied from the telephone line. A general surge circuit or the like may be used as the protection circuit, and thus a detailed description thereof will be omitted.

The line interface 502, like the line interface of the test control device, transmits a signal to the switching system and transmits a signal transmitted from the switching system to the corresponding module. In particular, the line interface 502 of the test terminal device functions to control the generation of DC voltage and current required for the operation of the test terminal device from the talk current provided from the switching system using a bridge diode or the like. As described above, the test terminal device of the present invention is preferably implemented to operate with only talk current without a separate power source.

The receive signal amplifier 504 and the transmit signal amplifier 510 function to amplify the DTMF signal transmitted from the test control device or the DTMF signal transmitted to the test control device. As the amplifier, various kinds of amplifiers such as a general differential amplifier may be used.

The DTMF receiver 506 functions to analyze the DTMF signal transmitted from the test control device. The DTMF receiver 506 analyzes the frequency of the transmitted DTMF signal to determine which number the DTMF signal corresponds to, and provides the analysis result to the low power processor 518 in the form of an electrical signal. The DTMF signal received by the DTMF receiver 506 may include a DTMF code corresponding to a test DTMF code transmitted by the test control device and a telephone number of the test control device.

The DTMF transmitter 508 functions to generate and transmit a DTMF signal to the test control device while the call is connected to the test control device. The DTMF transmitter 506 generates a preset DTMF code after the call control device makes a call and connects the call to the test control device. At this time, the preset code number information is provided from the low power processor 518, and generates a DTMF signal corresponding to the provided number and transmits it to the test control device. In addition, after the test operation is completed, the DTMF transmitter 508 generates a DTMF signal corresponding to the call completion code and transmits it to the test control device.

The constant voltage circuit 512 functions to provide a power source capable of operating the low power processor using the torque current even when the terminal is hooked on. As described above, the test terminal device according to the present invention preferably operates by a torque current without a separate power supply, and in this case, it is preferable to supply power to the low power processor when the hook-on state cannot receive the torque current. It is a problem.

The exchange system continues to supply constant power and determines whether the terminal is busy or not depending on whether it is using the supplied power. The constant voltage circuit 512 according to the present invention operates to supply power to the low power processor using power only to the extent that the exchange system does not determine the state of the terminal as a busy state, and to supply power to all circuits of the terminal in the hook-off state. . A more detailed configuration of the constant voltage circuit 512 will be described later in detail through separate drawings.

The hook switch 514 performs a hook-off or hook-on operation under the control of the low power processor 518 like the hook switch of the test control device.

The ring detector 516 detects a ring signal transmitted from the switching system, and provides ring sensing information to the low power processor 518 when receiving the ring signal more than a preset number of times.

The low power processor 518 controls the overall operation of the test terminal device and determines whether the test DTMF code transmitted from the test control device matches the preset DTMF code. Since the test terminal device is operated by torque current, it is preferable to use a processor that consumes low power.

6 is a block diagram showing a detailed configuration of a test terminal device according to a second embodiment of the present invention.

In comparison with FIG. 5, FIG. 6 further includes a calling party number recognition device between the line interface and the low power processor. The calling party number recognition device recognizes the telephone number of the test control device when a call is received from the test control device and provides the recognition result information to the low power processor. According to the second embodiment, the DTMF receiver does not receive the DTMF signal corresponding to the telephone number of the test control device, but receives only the test DTMF code.

Except that the calling party number recognition device is further added, the rest of the configuration is the same as Figure 5 will be omitted a detailed description thereof.

7 is a circuit diagram showing a detailed configuration of a constant voltage circuit according to an embodiment of the present invention.

Referring to FIG. 7, a constant voltage circuit according to an embodiment of the present invention includes a line 700, a bridge diode BD1, a plurality of resistors R1 and R2, a plurality of zener diodes ZD1 and ZD2, and a capacitor ( C1), diode D1, and hook switch 702.

In FIG. 7, line 700 is a line that receives torque current from an exchange system.

The torque current supplied from the exchange system is a direct current voltage with polarity present. The bridge diode functions to uniformly adjust the polarity of the supplied DC voltage, so that a DC voltage having a constant polarity is always provided internally by the bridge diode even when a voltage having a changed polarity is provided.

The resistor R1 is a resistor for voltage division and allows a preset voltage to be applied to the zener diode ZD1.

The zener diode ZD1 maintains a constant voltage so that a predetermined constant voltage is applied to the low power processor. Even if a ring voltage of 20 Hz is introduced by the zener diode ZD1, a constant voltage is applied to the low power processor. The capacitor C1 connected in parallel with the zener diode ZD1 functions as a smoothing capacitor to maintain a constant voltage even when an external voltage changes.

The hook switch 702 is in the off state when the hook-on state, so that power is not supplied to other circuits other than the low power processor, and in the hook-off state, the hook switch 702 is turned on so that power is also supplied to the other circuits. On-off operation of the hook switch 702 is controlled by a low power processor.

Resistor R2 is also a resistor for voltage distribution, and the divided voltage is provided to the zener diode ZD2, which in turn provides current to other circuits such as DTMF transceivers in the hook-off state, so that the switching system It can recognize the state of as hook-off state and keeps the voltage provided to other circuits constant.

The diode D1 serves to compensate for the lowering of the zener diode ZD1 due to the voltage drop.

As described above, according to the service state test system in the PSTN network according to the present invention, there is an advantage that can effectively detect the service abnormality state due to various obstacles by transmitting and receiving a test signal between the control device and the terminal.

In addition, according to the present invention, there is an advantage that can effectively test the service status in the PSTN network automatically without sending a separate personnel for the service status test.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention as set forth in the claims below It will be appreciated that modifications and variations can be made.

Claims (18)

A test control device connected with the telephone exchange system; And Include a test terminal device connected to the exchange system to be tested, The test control device connects a call with the test terminal device, receives a first test code from the test terminal device, determines whether the received first test code matches a preset first test code, and performs an exchange to test. Test the transmission status of the system, After the transmission state test is finished, the test terminal device connects a call with the test control device to receive a second test code from the test control device and whether the received second test code matches a preset test code. The service state test system of the PSTN network, characterized in that for testing the reception state of the test exchange system by determining whether or not. The method of claim 1, The first test code and the second test code transmitted by the test control device and the test terminal device is a service status test system in a PSTN network, characterized in that the DTMF code. The method of claim 1, After the test for the first test code is completed, the test terminal device transmits a call completion code to the test control device to release the call connection with the test control device, and calls the test number of the test control device to test Service status test system in the PSTN network, characterized in that to resume the call connection with the control device. The method of claim 3, And the test terminal apparatus receives a DTMF code corresponding to the telephone number of the test control apparatus from the test control apparatus and recognizes the telephone number of the test control apparatus. The method of claim 3, And the test terminal apparatus recognizes a telephone number of the test control apparatus by using a caller number recognition function when the test control apparatus attempts to connect a call. The method of claim 1, And the test terminal device operates by using a torque current provided from a switching system as a power source. The method of claim 6, The test terminal device may include a constant voltage circuit, and the constant voltage circuit may be configured to supply a predetermined low power to the processor of the test terminal device so that the switching system may continuously recognize the state of the test terminal device as the hook-on state when the hook-on state is in the hook-on state. And providing a power to other circuits of the test terminal device using the torque current of the switching system when in the hook-off state. A test control device for a test system including a test control device connected to an exchange system of a telephone station for a state test in a PSTN network and a test terminal device connected to an exchange system to be tested, A line interface connected with the telephone line; A DTMF receiver which dials the test terminal device and analyzes a first test code transmitted from the test terminal device when a call is connected; A DTMF transmitter for generating a second preset test code and transmitting the preset test code to the test terminal device when the test terminal device makes a call; A processor that controls the overall operation of a test control device and determines whether the received first test code matches a preset first test code to test a transmission state of a switching system to be tested; And a hook switch configured to perform a hook-off or a hook-on operation according to the control of the processor. The method of claim 8, And the DTMF transmitter generates a DTMF signal corresponding to the telephone number of the test control device and transmits the DTMF signal to the test terminal device. The method of claim 8, And the processor provides preset second test code information to the DTMF transmitter, and the DTMF transmitter generates a DTMF signal corresponding to the received second test code information. The method of claim 8, A memory for storing data necessary for a test and an operating algorithm program of the processor; And Test control device further comprises a connection for connecting to the operator terminal. A test terminal device used for a test system including a test control device connected to an exchange system of a telephone station and a test terminal device connected to an exchange system to be tested for a state test in a PSTN network. A line interface connected with the telephone line; A DTMF transmitter which, when the test control device makes a call and connects a call, generates a first test code which is set in advance and transmits it to the test control device; A DTMF receiver which dials the test control device and analyzes a second test code transmitted from the test control device when a call is connected; A low power processor that controls the overall operation of a test terminal device, and determines whether the received second test code matches a preset second test code to test a reception state of a switching system to be tested; Including a hook switch for performing a hook-off or hook-on operation under the control of the processor, And after the test on the first test code is completed, disconnects the call and attempts to connect the call to the test control device. The method of claim 12, And the test terminal device is driven by torque current from the exchange system. The method of claim 13, In the hook-on state, the switching system provides a predetermined low power source to the processor of the test terminal device so that the switching system can continuously recognize the state of the test terminal device as the hook-on state. And a constant voltage circuit for supplying power to the other circuits of the test terminal device by using the torque current. The method of claim 12, And an amplifier for amplifying the DTMF signal transmitted from the test control device and the DTMF signal to be transmitted to the test control device. delete The method of claim 12, And the DTMF receiver analyzes a DTMF signal corresponding to a telephone number of the test control device from the test control device and provides the same to the processor. The method of claim 12, And a caller number recognizer that recognizes a telephone number of the test control device when the test control device attempts to connect a call.

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