KR100693726B1 - Apparatus for testing a bus cable - Google Patents

Abstract

The present invention relates to a bus cable test apparatus capable of easily measuring a disconnection state of a bus cable used in an exchange, as well as an error due to a poor contact, and each bus signal input through a plurality of core wires of a bus cable. A cable connector to output the; A core line selecting unit configured to sequentially select two cores formed of a pair of cores based on a selection control signal; A signal analyzer and a determiner configured to determine whether the two bus signals are normal by comparing the same with respect to two bus signals output from the core selector and the magnitude of each bus signal; A display unit for displaying whether the bus cable is normal; The control unit provides different selection control signals corresponding to the types of bus cables to the core wire selection unit, and displays the type and normality of the bus cables connected to the cable connector based on the determination result from the signal analysis unit and the determination unit. In this configuration, the bus cable used in the electronic exchanger can be easily detected, as well as the state of each core wire constituting the bus cable and the connection state of the bus cable. It is possible to prevent the overall malfunction of the exchange due to the system and to reduce the system recovery time due to the failure of the bus cable.

Description

Bus cable test device {APPARATUS FOR TESTING A BUS CABLE}

1 is a block diagram schematically showing the configuration of a bus cable test apparatus according to a preferred embodiment of the present invention;

FIG. 2 is a circuit diagram exemplarily showing a detailed configuration of a bus cable test apparatus shown in FIG.

<Description of Symbols for Major Parts of Drawings>

11 cable connector 12 core selection section

13 signal analysis unit 14 determination unit

15 control unit 16 display unit

17: printer connection

The present invention relates to a bus cable test apparatus, and more particularly, to a bus cable test apparatus capable of detecting a bus cable error by measuring a bus signal of a bus cable used in an electronic exchanger.

In connection with the present invention, the T / B bus cable generally used in the electronic exchanger is almost impossible to detect even if a defect occurs inside the cable, which causes an overall malfunction of the exchanger system.

In detail, the signals currently used in the T / B bus of the electronic exchange are composed of four signals: clock, data, frame sync, and assert, and the B bus is redundant. The same pair of signals is routed through the common processor board (CPB) to the bus cable, and the two pairs of signals are routed to the bus cable through the Cisco Certified Internetwork Professional (CCI) board, which is also redundant to the T bus.

As a result, since the structure of the T / B bus cable carrying the signal is double or quadruple, it is impossible to detect it in advance even if a disconnection occurs. Only after a system failure occurs is there a problem of recognizing a bad bus cable.

In addition, even when the failure of the bus cable is recognized, it is impossible to detect the exact point of failure, and thus there is an uneconomical problem such as replacing the entire bus cable. In addition, there is a problem that it is impossible to detect the exact failure point even when the error of the bus cable is recognized.

Therefore, to solve the above-described problems of the prior art of the present invention, to provide a bus cable test apparatus that can easily measure whether the error due to poor contact, as well as the disconnection state of the bus cable used in the exchanger Its purpose is to.                         

In order to achieve the above object, the present invention provides a bus cable test apparatus for detecting an error on a bus cable of an exchanger,

A cable connector connected to a bus cable of the exchanger through a plurality of connection pins and outputting respective bus signals input through a plurality of core wires of the bus cable;

Core selector for sequentially outputting two bus signals A, B from each of the selected cores by sequentially selecting two cores composed of a pair of cores of the bus cable connected through the cable connector based on a selection control signal ;

A signal analyzer and a determiner configured to determine whether the two bus signals are normal by comparing the two bus signals output from the core selector with the same and the magnitudes of the respective bus signals;

A display unit for displaying whether the bus cable is normal; And

The selection control signal corresponding to the type of bus cable is provided to the core selection unit, and the type and normality of the bus cable connected to the cable connector are determined based on the determination result from the signal analyzing unit and the determining unit. Provided is a bus cable test apparatus, comprising a control unit displaying through the display unit.

Hereinafter, a bus cable test apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing a schematic configuration of a bus cable test apparatus according to an exemplary embodiment of the present invention, and includes a cable connector 11, a core wire selecting unit 12, a signal analyzing unit 13, and a determining unit ( 14), a control unit 15, a display unit 16, and a printer connection unit 17.

Referring to Figure 1, first, the cable connector 11 is provided for the interconnection of the bus cable of the exchanger and the bus cable test apparatus of the present invention in order to measure whether the bus cable is disconnected or contacted according to the present invention. As a means, the number of connection pins formed in the cable connector 11 can be varied depending on the type of bus cable. For example, since the B-Bus and T-Bus cables of the TDX-1AB switch are composed of 24 pins, the number of connection pins configured in the cable connector 11 is also implemented as 24 pins.

In addition, the core wire selector 12 shown in FIG. 1 is paired (two) by the control of the control unit 15 which describes each core wire of the bus cable connected through each connection pin of the cable connector 11. Selected sequentially, and performs the function of transmitting the two signals (A, B) from the selected core wire to the signal analyzer 13, which can be easily implemented using a multiplexer or the like. Do.

Meanwhile, the signal analyzer 13 compares whether the signals A and B are the same from the two signals A and B provided from the core selector 12, and compares the level magnitudes of the signals. As a means for transmitting a result of the comparison to the determination unit 14, the signal analysis unit 13 can be easily implemented using a comparator and a logic circuit.

The determination unit 14 determines the state of the cable based on the comparison result provided from the signal analysis unit 13 and stores the result. The determination unit 14 uses a flip-flop or the like. Implementation is possible.

On the other hand, the control unit 15 is a means for controlling the overall operation of the bus cable test apparatus according to the present invention, the control unit 15 is pre-stored a variety of program logic (Program Logic) necessary for the control of the bus cable test apparatus have. That is, the controller 15 prestores logic for controlling each constituent means of the bus cable test apparatus according to the present invention, and detects the type, disconnection or contact state of the bus cable by the logic. In addition, as described above, the core wire selector 12 generates a control signal for sequentially selecting each of the core wires connected through each connection pin of the cable connector 11.

In addition, the display unit 16 shown in FIG. 1 displays an error of the bus cable and the number of the pin where an error occurs according to the control signal of the controller 15 based on the determination result of the determination unit 14 described above. The user can easily recognize whether the bus cable connected to the cable connector 11 is disconnected and a pin number in which an error occurs. The display unit 16 can be easily implemented with an LCD or the like.

In addition, the printer connection unit 17 is an additionally configured means for the user's convenience, and is provided for connection with an external printer not shown. That is, when the user wants to print the measurement result in the process of measuring the error of the bus cable, it is a connection means for connecting the external printer through the printer connection unit 17.

Meanwhile, FIG. 2 is a circuit diagram illustrating an actual circuit configuration of the bus cable test apparatus shown in FIG. 1 by way of example. The circuit diagram shown in FIG. 1 shows whether a T / B bus is disconnected in the TDX-1AB exchanger. And a circuit diagram of a test apparatus capable of measuring a contact state. Therefore, hereinafter, a detailed configuration of the bus cable test apparatus according to the present invention will be described in detail by taking an error measuring procedure for the T / B bus cable in the TDX-1AB exchange as an example.

First, in FIG. 2, the configuration of the display unit 16 described with reference to FIG. 1 is omitted, and only the connection terminal 16-1 for connecting the display unit 16 is illustrated.

Referring to FIG. 2, the cable connector 11 includes 24 connection pins so as to transmit a T / B bus signal input through each connection pin to the core wire selector 12. At this time, the actual number of bus signals input through the bus connector 11 is 16 as shown in FIG.

Meanwhile, the core wire selector 12 is implemented using two analog multiplexer 4067 elements as shown in FIG. 2, and each multiplexer is transmitted from the cable connector 11 under the control of the controller 15. The bus signals are selected and output one by one. At this time, the two bus signals A and B are transmitted to the signal analyzer 13.

The signal analyzer 13 is implemented using a plurality of comparator elements LM339, an AND gate, an XOR gate, and the like, as shown in FIG. 2. Here, the comparator element serves to compare the magnitudes of the two signals A and B selected by the core selector 12 described above, and the AND gate and the XOR gate compare whether the two signals A and B are the same. Done. That is, the signal analyzer 13 calculates a difference between the two bus signals A and B provided from the core selector 12 and outputs a comparison signal corresponding thereto, and two bus signals. It is composed of a logic circuit that determines whether or not the same for (A, B) and outputs a corresponding logic value.

The comparison signal and the logic value according to the result are provided to the determination unit 14, which is composed of two flip-flop elements 4043 as shown in FIG. Based on the comparison signal and the logic value output from the unit 13, it is determined whether the state of the A signal and the not A signal is '0' or '1', and the determination signal is provided to the controller 15 accordingly.

Meanwhile, the controller 15 is implemented using an 8951 micro-processor unit (MPU) as shown in FIG. 2, and as described above, the controller 15 includes program logic for controlling each component of the bus cable test apparatus. In particular, logic for allowing the above-described core wire selector 12 to sequentially select two bus signals input through each connection pin of the cable connector 11 is included. Then, on the basis of each determination signal provided from the determination unit 14, by checking the presence or absence of abnormality for each core wire selected by the core wire selection unit 12, and transmits to the display unit connector 16-1, in FIG. The display unit (for example, LCD), not shown, displays the presence or absence of abnormalities for each core wire of the bus cable. That is, the display unit 16 displays the number and abnormality of the connection pins or core wires.

The printer connection unit 17 shown in FIG. 1 is implemented using an RS232C terminal as shown in FIG. 2, and is connected to an external printer (not shown) to output a test result of a bus cable.

1 and 2, the test process of the bus cable test apparatus according to the present invention will be described in detail with reference to the following.

First, when the bus cable test apparatus according to the present invention is connected with a bus cable to the cable connector 11 by a user's operation and an operation signal for performing a test is input, the control unit 15 stores the program logic stored therein. By doing so, before the bus cable is tested for abnormality, a process for determining the type of bus cable connected to the cable connector 11 is performed.

1 and 2, when an arbitrary bus cable is connected through a plurality of connection pins provided in the cable connector 11 and a bus signal input from each core wire of the bus cable is input to the cable connector 11, The controller 15 generates a control signal to the core selector 12 to sequentially select the A and B signal pairs to match the B bus structure or the T bus structure. That is, the control unit 15 selects two core wires corresponding to the B bus structure and the T bus structure to determine whether the bus cable connected to the cable connector 11 is a B bus cable or a T bus cable. Is generated and transmitted to the core selection unit 12.

Accordingly, the core wire selector 12 is based on the control signal of the control unit 15 and thus, two bus signals from each bus signal input from the cable connector 11 through the respective multiplexers, that is, the A signal in the case of the B bus signal. Select and output the B signals (ID7, ID6, ID5, ID4) corresponding to (ID0, ID1, ID2, ID3), and the A signal (ID0, ID1, ID2, ID3, ID8, ID9, ID10) for the T bus signal. , The B signals (ID4, ID5, ID6, ID7, ID12, ID13, ID14, and ID15) corresponding to ID11 are sequentially selected and output.
That is, in the case of the B bus signal, the A signal and the B signal are each selected as a pair of (ID0, ID7), (ID2, ID6), (ID3, ID5), and (ID4, ID4), and each pair of signals is one bus. Since the signal is applied from the cable, the disconnection and error of the corresponding bus cable can be determined by comparing the magnitude of each pair of signals.

In this case, the selected A and B signals are provided to the signal analyzer 13, and the signal analyzer 13 compares the A and B signals provided from the core selector 12 as described above, respectively. A logic value based on whether the signals are the same and the difference between the two signals is provided to the determination unit 14.

At this time, the determination unit 14 detects whether the A and B signals are '0' or '1' based on the comparison result and the logic value from the signal analysis unit 13 and provides the detection result to the control unit 15. As a result, the control unit 15 determines the type (type) of the bus cable currently connected to the cable connector 11.

In detail, if the A = 1 signal has not been detected by the determination unit 14, the controller 15 determines that the bus cable is not connected to the cable connector 11 and displays a corresponding message. 16) or to a printer (not shown) connected through the printer connection unit 17.

On the contrary, when the core selector 12 selects a signal pair corresponding to the B-bus structure under the control of the controller 15, the determination unit 14 determines that A = B (A <> B is False). The number of detections is calculated. Further, when the core line selector 12 selects a signal pair corresponding to the T-bus structure under the control of the controller 15, the determination unit 14 determines that A = B (A <> B is False). The number of detections is calculated.

At this time, the control unit 15 compares the calculated detection times, and if the result of the comparison is that A = B is detected a plurality of times in the B bus signal pair and A = B is not detected in the T bus signal pair, the cable connector It is possible to determine that the bus cable connected to (11) is the B bus cable.

On the contrary, if A = B is detected a plurality of times in the T-bus signal pair and A = B is not detected in the B-bus signal pair as a result of the comparison with respect to the respective detection times described above, the controller 15 controls the cable connector 11. It is possible to determine that the bus cable connected to) is a T-bus cable.

In addition, when another comparison result is output, the controller 15 determines that another type of bus cable, that is, a cable other than the T / B bus cable is connected, and displays the error result according to the display unit 16 or the printer connection unit ( 17) to be connected to the printer (not shown) connected through.

On the other hand, the determination process of the type of bus cable connected to the cable connector 11 is completed through each of these processes, and as a result of the determination, the type of bus cable connected to the cable connector 11 is B bus cable or T bus cable. In this case, the controller 15 generates a control signal to the core wire selector 12 to generate a control signal for sequentially selecting each core wire from the cable connector 11 according to the type of the bus cable. Or test the T-bus cable.

First, the bus cable connected to the cable connector 11 through the above-described bus cable type determination process is determined to be a B bus cable, and thus the inspection process for the B bus cable will be described as follows.                     

The control unit 15 generates a control signal to the core wire selection unit 12 to control each of the core wires of the B bus cable connected to the cable connector 11 in order to sequentially select one pair (two) corresponding to the B bus structure. The core wire selector 12 selects each core wire corresponding to the B bus cable structure and provides the bus signals A and B to the signal analyzer 13 accordingly.

Then, the signal analyzer 13 compares the pair of A and B bus signals to be equal to the two signals and the difference between the two signals to provide the comparison result to the determination unit 14. Accordingly, the determination unit 14 determines the state of the B-bus cable connected to the cable connector 11 based on the comparison result and provides the determination result to the control unit 15, if A = 1 signal is not detected. Otherwise, the controller 15 determines that the core wire currently selected by the core wire selection unit 12 is disconnected and outputs whether the wire is disconnected to a printer (not shown) connected through the display unit 16 or the printer connection unit 17. .

If the A <> B signal or the A <B signal is detected, the controller 15 determines that the state of the core wire is abnormal. At this time, the A <B signal is divided into approximately three steps (for example, somewhat bad, bad, very bad) according to the difference between the A and B signals to display the state of the B bus cable on the display unit 16 or the printer connection unit 17. It will be output to the printer (not shown) connected through.

On the other hand, when the bus cable connected to the cable connector 11 is determined to be a T-bus cable through the above-described bus cable type determination process, the control unit 15 corresponds to the T-bus structure in the core wire selector 120, respectively. The control signal for sequentially selecting the core wires of the control unit is generated and provided to the core wire selection unit 12. The control unit 15 also applies to each of the T bus signals output from the core wire selection unit 12 as described above. Through the same process as that of the bus signal, whether the wire is disconnected and an error state can be detected.

As described above, the bus cable test apparatus according to the present invention can easily detect not only the disconnection of the bus cable used in the electronic exchange but also the state of each core wire constituting the bus cable and the connection state of the bus cable. The effect is to prevent the overall malfunction of the exchange due to the bus cable and to reduce the system recovery time due to the failure of the bus cable.

In addition, a preferred embodiment of the present invention is disclosed for the purpose of illustration, those skilled in the art will be able to make various modifications, changes, additions, etc. within the spirit and scope of the present invention, such modifications and modifications belong to the following claims You will have to look.

Claims (7)

In the bus cable test apparatus for detecting an error on a bus cable of an exchange, A cable connector connected to a bus cable of the exchanger through a plurality of connection pins and outputting respective bus signals input through a plurality of core wires of the bus cable; Core selector for sequentially outputting two bus signals A, B from each of the selected cores by sequentially selecting two cores composed of a pair of cores of the bus cable connected through the cable connector based on a selection control signal ; A signal analyzer and a determiner configured to determine whether the two bus signals are normal by comparing the two bus signals output from the core selector with the same and the magnitudes of the respective bus signals; A display unit for displaying whether the bus cable is normal; And The selection control signal corresponding to the type of bus cable is provided to the core selection unit, and the type and normality of the bus cable connected to the cable connector are determined based on the determination result from the signal analyzing unit and the determining unit. And a control unit for displaying through the display unit. The method of claim 1, The core cable selector is composed of a plurality of multiplexers. The method of claim 1, The signal analyzer may include a plurality of comparators configured to calculate a difference between the two bus signals provided from the core line selector and output a corresponding comparison signal, and determine whether the two bus signals are identical to each other and determine the same. It consists of a logic circuit that outputs a logic value And the determination unit determines the state of the bus cable based on the comparison signal and the logic value provided from the signal analysis unit. The method of claim 1, And the display unit comprises an LCD which displays the number and normality of the core wires selected by the core wire selection unit based on a control signal of the controller. The method of claim 1, The bus cable test apparatus further includes a printer connection unit configured to output the normal state of the bus cable through a printer connected to the outside. The method according to any one of claims 1 to 5, And the bus cable connected to the cable connector is a B / T bus cable. The method of claim 6, The control unit, Detecting when two bus signals transmitted from each of the selected cores are identical (hereinafter referred to as n) in the first case in which each core corresponding to the B bus structure is sequentially selected through the core selection unit; Detecting when two bus signals transmitted from each of the selected cores are the same (hereinafter referred to as m) in a second case in which each core corresponding to the T bus structure is sequentially selected through the core selection unit; If the n is detected a plurality of times in the first case and the m is not detected in the second case, determine the bus cable connected to the cable connector as a B bus cable; When m is detected a plurality of times in the second case and n is not detected in the first case, the bus cable connected to the cable connector is determined as a T bus cable, and the normality of each bus cable is tested. Bus cable testing device.

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