KR20120137855A - Sensing circuit for mailfunction of data line of multi-drop communication circuit - Google Patents

Abstract

PURPOSE: A data line abnormal sensing circuit of a multi drop communication circuit is provided to rapidly determine a cause of communication error in a multi drop communication circuit in a simple structure. CONSTITUTION: A switching unit(20) performs switching about a data line. A switching controlling unit(30) separates the connection of the data line about the switching unit. A first sensing unit(40) inputs a signal received from a data receiving unit. A second sensing unit(50) inputs a signal outputted from a data transceiving unit. A control unit(60) outputs a signal which is determined as malfunction from the first sensing unit and the second sensing unit.

Description

Sensing circuit for mailfunction of data line of multi-drop communication circuit

The present invention relates to a data line abnormality detection circuit of a multidrop communication circuit for detecting an abnormality of a data line and a communication circuit in a multidrop communication circuit using a data line of a common wiring. Data of a product with a built-in multi-drop communication circuit that uses a line, and data of a multi-drop communication circuit that can more quickly and easily repair a malfunction or malfunction that may occur in a communication circuit related thereto. It relates to a line abnormality detection circuit.

In the case of a multi-family house or apartment house, a common wiring data line is generally used, and communication equipment for data communication for each unit space is provided for the data line. At this time, since the data line is installed in the external common structure, the user of the multi-drop communication circuit should be provided in the unit space even when an accident such as short-circuit of the data line of the common wiring and the GND of the common wiring occurs due to an external factor. There is a problem that it is difficult to determine whether there is a problem with the old equipment or a problem with the data communication line, and accordingly, it was difficult to quickly remove the communication failure. In particular, the data transmission unit for data transmission of the communication device includes at least two transistors involved in the high voltage output and at least one transistor involved in the low voltage output in order to transmit the data. The emitter and collector may conduct due to the failure of the transistor. At this time, it is difficult to determine whether these transistors are defective in time.

Accordingly, an object of the present invention is to provide a data line abnormality detection circuit of a multi-drop communication circuit capable of quickly determining the cause of a communication failure in a multi-drop communication circuit with a simple structure.

In addition, another object of the present invention is to provide a data line abnormality detection circuit of a multi-drop communication circuit capable of quickly eliminating communication failure and enabling normal operation in a multi-drop communication circuit.

It is still another object of the present invention to provide a data line abnormality detection circuit of a multi drop communication circuit capable of continuously monitoring a communication state in a multi drop communication circuit.

According to the present invention, in a communication device having a multi-drop communication circuit, an interface 10 for connecting to a data line for communicating with the outside and a switching unit for switching for a data line connected to the interface 10 ( 20) connected to the switching control unit 30 and the switching unit 20 for disconnecting the data line in the case of communication failure with respect to the switching unit 20 and in parallel with the data receiving unit 40A for receiving data. The second sensing unit 50 is connected to the first sensing unit 40 and the switching unit 20 for receiving the received signal, and receives the signal immediately before being output from the data transmitting unit 50A for transmitting data. , And are connected to the first sensing unit 40 and the second sensing unit 50 to be maintained for a predetermined time after the change of the signal S input from the first sensing unit 40 and the second sensing unit 50 is changed. In case of malfunction, output a signal Is provided over the data lines, multi-drop communication circuit detecting circuit including a control unit 60.

Here, it is preferable to further include a comparator 70 between the switching unit 20 and the first sensing unit 40.

In addition, the comparator 70 preferably includes a comparator 72 that inverts the input signal and outputs the input signal by comparing the reference voltage after the input signal is input to the inverting terminal.

In addition, the switching unit 20 is preferably made of a relay element for shorting the data line to the interface 10 under the control of the switching control unit 30.

In addition, when the malfunction signal is output by the control unit 60, the switching control unit 30 is preferably to block the connection to the external data communication line to the switching unit 20.

In addition, the data receiver 40A includes an inverter 42 for receiving and inverting an output signal from the comparator 70 and inputs a signal output from the inverter 42 to the controller 60, and detects the first signal. The unit 40 is connected to an output terminal of the comparator 70, and is composed of an inverter 46 connected through a diode 44, and preferably inputs a signal output from the inverter 46 to the controller 60. Do.

In addition, the data transmitter 50A receives the data from the controller 60 and outputs the data to the switching unit 20 so that the resistor R1 in which the inverter 51, the diode 52, and the inverter 53 are sequentially connected to each other is provided. The base is connected to the first transistor 54 connected to the base and the emitter grounded, the resistor R2 connected to the collector of the first transistor 54, and the resistor R3 is connected between the base and the emitter. The second transistor 55 connected to the power supply terminal and the diode 56 connected to the collector, the collector connected to the diode 56, the base connected to the inverter 51 via a resistor R4, and the emitter It is preferable that the third transistor 57 is grounded, and a connection point of the collector of the third transistor 57 and the diode 56 is connected to the switching unit 20.

In addition, the high signal H is normally input to the input side of the inverter 53 of the data transmitter 50A by the controller 60, and the second detector 50 is connected to the collector of the second transistor 55. It is preferable that it consists of a diode 58 to be connected and an inverter 59 connected to the diode 58.

In addition, the control unit 60 is connected to the switching control unit 30, the data receiving unit 40A, the first sensing unit 40, and the data transmitting unit 50A, and normally causes the switching control unit 30 made of an oscillation element. The oscillation is made so that the data communication line is connected to the switching unit 20 made of a relay element, and when the signal determined to be malfunction by the control unit 60 is output, the switching control unit 30 stops oscillation. Thus, the data communication line is disconnected from the switching unit 20.

In addition, the same high signal (H) is normally output from the first sensing unit 40 and the second sensing unit 50, and at least one of the first sensing unit 40 or the second sensing unit 50 in case of malfunction. Preferably, one output signal is outputted with a low signal (L).

In addition, when the signals of the respective output terminals B and C of the first sensing unit 40 and the second sensing unit 50 connected to the control unit 60 are all initially high (H), the output stage is later for a predetermined time. When one or more of (B, C) changes to low (L), the controller 60 outputs a signal that determines that a problem has occurred in the transistors 54, 55, 57 of the data line or the data transmitter 50A. In this case, it is preferable that the switching controller 30 disconnects the connection from the external data line in the switching unit 20.

In addition, when the data transmission unit 50A operates by the control unit 60 to transmit data, the output terminal C outputs a signal inverted from the transmission data by the inverter 59 connected to the data transmission unit to the control unit 60. The input terminal B outputs a signal such as transmission data and inputs it to the control unit 60.

If the data transmitted to the output terminal C and the inverted data are not output, it may be determined that a problem has occurred in the transistors 54 and 55. If the same data as the data transmitted to the output terminal B is not output, the first detection may be performed. It may be determined that a problem occurs in the unit 40 and the comparison unit 70.

In addition, when the transmission data is not generated by the controller 60, the high signal H is output to the output terminal B of the first detector 40 for a predetermined time, and the output terminal of the second detector 50 is output. (C) When the low signal L is output for a predetermined time, the controller 60 preferably outputs a signal that the transistors 54 and 55 are defective.

In addition, before the switching unit 20 disconnects the connection with the data line by the controller 60, a low signal L is output to the output terminal B of the first sensing unit 40, and the second sensing unit 50 is output. A high signal (H) is output to the output terminal C of the control panel). After that, the switching unit 20 disconnects the connection with the data line by the controller 60, and then the output terminal B of the first sensing unit 40. If the low signal (L) is output to the output terminal (C) of the second sensing unit 50, when the high signal (H) is output to the control unit 60 outputs a signal that the third transistor 57 is bad. It is preferable.

In addition, before the switching unit 20 disconnects the connection to the external data line by the controller 60, a low signal L is output to the output terminal B of the first sensing unit 40, and the second sensing unit ( The high signal H is output to the output terminal C of the 50. After that, the switching unit 20 disconnects the connection with the external data line by the controller 60, and then the output terminal of the first sensing unit 40. When the high signal H is output to the output signal C of the second sensing unit 50 and the high signal H is output to the output signal C of the second sensing unit 50, the controller 60 outputs a signal indicating that an external data line is defective. It is preferable.

Therefore, according to the present invention, it is possible to quickly determine the cause of the communication failure.

1 is a data line abnormality detection circuit diagram of a multi-drop communication circuit according to a preferred embodiment of the present invention.
2 is a table illustrating output results of the first sensing unit and output of the second sensing unit in the case of a communication failure in the data line abnormality sensing circuit of the multi-drop communication circuit according to the preferred embodiment of the present invention.
FIG. 3 is a table illustrating an output result of the first sensing unit and an output of the second sensing unit in a normal data transmission output in the data line abnormality sensing circuit of the multi-drop communication circuit according to an exemplary embodiment of the present invention.
FIG. 4 is a table illustrating an output result of the first sensing unit and an output result of the second sensing unit in the case of a failure of the first transistor and the second transistor of the data transmitter in the data line abnormality sensing circuit of the multi-drop communication circuit according to the preferred embodiment of the present invention. to be.
FIG. 5 is a diagram illustrating an output result of a first sensing unit before and after switching of a switching unit and an output result of a second sensing unit in a data line abnormality sensing circuit of a multi-drop communication circuit according to an exemplary embodiment of the present invention. Table.
FIG. 6 is a diagram illustrating an output of a first sensing unit and a second sensing unit before and after switching of a switching unit when a data communication line connected to an external line is connected to the GND of a common wiring in a data line anomaly sensing circuit of a multi-drop communication circuit according to an exemplary embodiment of the present invention. Table shows the output result of the sensor.

Hereinafter, a data line abnormality detection circuit of a multi-drop communication circuit according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a data line error detection circuit diagram of a multi-drop communication circuit according to a preferred embodiment of the present invention, Figure 2 is a communication line failure detection circuit in the data line error detection circuit of a multi-drop communication circuit according to a preferred embodiment of the present invention. Table 1 is a table showing the output of the first sensing unit and the output of the second sensing unit, Figure 3 is a data line abnormal detection circuit of the multi-drop communication circuit according to an embodiment of the present invention and the output of the first sensing unit in the normal data transmission output 4 is a table illustrating output results of the second sensing unit, and FIG. 4 is a diagram illustrating a data line abnormality sensing circuit of a multi-drop communication circuit according to an exemplary embodiment of the present invention. Table of the output and the output result of the second detection unit, Figure 5 is a multi-drop communication according to a preferred embodiment of the present invention Table 3 shows the output results of the first sensing unit before and after switching of the switching unit and the output of the second sensing unit when the third transistor failure of the data transmitter in the data line abnormality sensing circuit of FIG. 6 is shown. In the data line error detection circuit of the drop communication circuit, the data communication line connected to the outside is a table showing the output results of the first sensing unit and the output of the second sensing unit before and after switching of the switching unit when the GND of the common wiring is shorted.

As shown in FIG. 1, a data line abnormality detection circuit of a multi-drop communication circuit according to an exemplary embodiment of the present invention is connected to an interface 10 and an interface 10 for connection to a data line for communicating with an external device. A switching unit 20 for switching data lines, a switching control unit 30 for separating data lines in case of a communication failure with respect to the switching unit 20, and data for receiving data connected to the switching unit 20 A first detecting unit 40 connected to the receiving unit 40A in parallel to sense a data receiving input to monitor whether data communication is interrupted, and a data transmitting unit 50A connected to the switching unit 20 to transmit data. The second sensing unit 50 for sensing the data transmission output to monitor the failure of data communication, and the first sensing unit 4 is connected to the first sensing unit 40 and the second sensing unit 50. When the signal of the data communication failure is input from 0) and the second sensing unit 50, the switching of the switching unit 20 is turned off with respect to the switching control unit 30. At this time, the first sensing unit 40 and the second And a control unit 60 for determining whether there is a failure in the data communication line and the data transmitter 50A according to the change of the input signal of the sensor 50.

On the other hand, it is preferable to further include a comparator 70 between the switching unit 20 and the first sensing unit 40.

The interface 10 is for connecting a data communication line for communicating with the outside to a communication device, and may be made of a connection terminal.

The switching unit 20 is connected to / disconnected from / to the interface 10 under the control of the switching control unit 30. The switching unit 20 is preferably made of a relay element. Alternatively, the switching unit 20 may be formed of a transistor, which is a switching element.

The switching control unit 30 is a configuration for outputting a control signal for controlling the on / off to the switching unit 20, and is preferably made of an oscillation element oscillated by the control unit 60. At this time, the switching control unit 30 oscillates when the control unit 60 is in a normal communication state so as to connect the communication device to the external data communication line with respect to the switching unit 20, and may be in an abnormal communication state. In this case, the communication unit is separated from the external data communication line with respect to the switching unit 20.

Therefore, the switching unit 20 made of a relay connects a communication device with an external data communication line when an oscillation signal is input by the switching control unit 30 made of an oscillation element, and an abnormal oscillation occurs due to a problem of the control unit 60 or The communication device is separated from the external data communication line when the non-oscillation signal is input.

The comparator 70 includes a comparator 72 that inverts the input signal and outputs the input signal by comparing the reference voltage after the input signal is input to the inverting terminal.

The data receiver 40A includes an inverter 42 for receiving the output signal from the comparator 70 and inverting the input signal. The data receiver 40A inputs the signal output from the inverter 42 to the controller 60.

The first sensing unit 40 is connected to the output terminal of the comparator 70 and consists of an inverter 46 connected via a diode 44 and inputs a signal output from the inverter 46 to the controller 60. Let's do it.

The data transmitter 50A receives the data from the controller 60 and outputs the data to the switching unit 20 so that the resistor R1 to which the inverter 51, the diode 52, and the inverter 53 are sequentially connected is a base. A base connected to a first transistor 54 connected to a grounded emitter and a resistor R2 connected to a collector of the first transistor 54, and a resistor R3 connected between a base and an emitter, and a power supply terminal. A second transistor 55 having a diode 56 connected to the collector, a collector connected to the diode 56, connected to the base via a resistor R4 with respect to the inverter 51, and the emitter grounded. A third transistor 57 is formed, and a connection point of the collector of the third transistor 57 and the diode 56 is connected to the switching unit 20. At this time, it is preferable that a high signal is normally input to the input side of the inverter 53 by the control unit 60.

The second sensing unit 50 includes a diode 58 connected to the collector of the second transistor 55 and an inverter 59 connected to the diode 58.

The control unit 60 is connected to the switching control unit 30, the data receiving unit 40A, the first sensing unit 40, and the data transmitting unit 50A, and oscillates by the switching control unit 30 made of an oscillation element. When the data communication line is connected to the switching unit 20 made of a relay element, the signal input from the first sensing unit 40 and the second sensing unit 50 is a signal corresponding to a communication failure. The switching control unit 30 causes the oscillation to stop so that the data communication line is separated from the switching unit 20.

On the other hand, the control unit 60 and the signal received originally received from the first sensing unit 40 and the second sensing unit 50 continuously continuously for a predetermined time in the state that the external data communication line is connected by the switching unit 20 and The same signal, for example, a high signal is monitored to determine if a change in the signal is determined as a communication failure.

In the data line anomaly detection circuit of the multi-drop communication circuit according to the preferred embodiment of the present invention, the control unit 60 switches so that the same high signal is normally output from the first and second sensing units 40 and 50. A high (H) signal is applied to the input terminal of the unit 20 and the inverter 53.

That is, as shown in FIG. 2, for example, signals of the output terminals B and C of the first sensing unit 40 and the second sensing unit 50 connected to the control unit 60 are all initially high. In the (H) state and when one or more of these output stages (B, C) are turned low (L) for a period of time later in the transistor (54, 55, 57) of the data communication line or data transmitter (50A). It is determined that a problem has occurred in at least one, and accordingly, the control unit 60 outputs a signal to stop the oscillation so that the external data line is separated from the switching unit 20 made of a relay element. .

Thereafter, the control unit 60 receives signals from the first sensing unit 40 and the second sensing unit 50 to determine a fault or a defective position according to the signal. An operation thereof will be described with reference to FIGS. 3 to 6.

First, as illustrated in FIGS. 1 and 3, when the controller 60 transmits low L data, the output of the inverter 51 becomes high (H) and the collector of the third transistor 57 is low ( L), the output terminal of the comparator 70 is output high (H), the low (L) output of the first sensing unit 40 is input to the control unit 60 again. That is, the same data as the data transmitted from the control unit is input back to the control unit through the first sensing unit 40, where the input of the inverter 53 connected to the control unit 60 is high (2). Since there is no change to the H) state, it is in the high (H) state opposite to the transmitted data.

When the control unit 60 transmits the high (H) data, the output of the inverter 51 becomes low (L) and the collector of the third transistor 57 becomes high (H). The output L of the comparator 70 outputs a low L, and the high H output of the first detector 40 is input to the controller 60 again. At this time, the second detector 50 inputs the input of the inverter 53 connected to the controller 60 to a low (L) state, and the high (H) signal output from the inverter 53 operates the first transistor 54. As a result, a high H is output to the collector of the second transistor 55, and the output of the second sensing unit 50 is in a low L state.

Meanwhile, as illustrated in FIGS. 1 and 4, when a failure occurs in the first transistor 54 and the second transistor 55 so that the collector and emitter of the first transistor 54 are energized, the first detection is performed. The high signal H is output to the output terminal B of the unit 40, and the low signal L is output to the output terminal C of the second sensing unit 50, and the collector and the emitter of the second transistor 55 are output. Even when the current is energized, the high signal H is output to the output terminal B of the first sensing unit 40 and the low signal L is output to the output terminal C of the second sensing unit 50. When such a signal is input to the controller 60, the controller 60 outputs a signal that the first transistor 54 or the second transistor 55 is defective.

1 and 5, when a failure occurs in the third transistor 57 and the collector and emitter of the third transistor 57 are energized, the controller 60 controls the switching unit ( Before the 20 separates the external data line, the low signal L is output to the output terminal B of the first sensing unit 40, and the high signal H is output to the output terminal C of the second sensing unit 50. Is output. After that, after the switching unit 20 disconnects the connection to the external data line by the control unit 60, a low signal L is output to the output terminal B of the first sensing unit 40, and the second sensing unit is output. The high signal H is output to the output terminal C of 50. When such a signal is input to the controller 60, the controller 60 outputs a signal that the third transistor 57 is defective.

1 and 6, when a failure occurs in an external data line and the external data line is shorted with the GND line among the common lines, the control unit 60 switches the external unit 20 to the external data. Before disconnecting the line, the low signal L is output to the output terminal B of the first sensing unit 40 and the high signal H is output to the output terminal C of the second sensing unit 50. . After that, after the switching unit 20 disconnects the connection with the external data line by the control unit 60, a high signal H is output to the output terminal B of the first sensing unit 40, and the second sensing unit is output. The high signal H is output to the output terminal C of 50. When such a signal is input to the controller 60, the controller 60 outputs a signal that an external data line is defective.

Therefore, it is possible to quickly determine the location of the failure to be able to replace the defective device or parts quickly.

As such, the control unit 60 receives the change in the signal input to the data receiving unit 40A and the signal immediately before being output from the data transmitting unit 50A so as to determine whether or not the defective position is based on the combination of these signal changes. Doing.

The controller 60 preferably consists of a CPU programmed to operate as described above.

On the other hand, it is possible to change various elements for combining the signal input to the data receiving unit 40A input to the control unit 60 and the change of the signal immediately before being output from the data transmitting unit 50A to the switching unit 20. Will be self explanatory.

In addition, although the switching controller 30 is described as an oscillation element for oscillation known in the foregoing, it is not necessarily made of an oscillation element, and the switching control unit 30 and the switching unit 20 are controlled by the control unit 60. Switching element for switching, for example, when the abnormal signal is input from the first sensing unit 40 and the second sensing unit 50 can cut off the connection of the external data line, for example, It may consist of a field effect transistor.

10: interface
20: switching unit
30: switching control unit
40A: data receiver
40: first detection unit
42, 46, 51, 53, 59: inverter
R1, R2, R3, R4: Resistance
44, 52, 56, 58: diode
50A: data transmitter
50: second detection unit
54, 55, 57: transistor
60:
70: comparison unit
72: comparator

Claims (14)

In a communication device for a multi-drop communication circuit,
An interface 10 for connecting to a data line for communicating with the outside;
A switching unit 20 connected to the interface 10 for switching the data lines;
A switching controller 30 for disconnecting a data line from a communication failure with respect to the switching unit 20;
A first sensing unit 40 connected to the switching unit 20 and connected in parallel with the data receiving unit 40A for receiving data to receive a received signal;
A second sensing unit 50 connected to the switching unit 20 for receiving a signal immediately before being output from the data transmitting unit 50A for transmitting data; And
Malfunction when connected to the first sensing unit 40 and the second sensing unit 50 and lasts for a predetermined time after the change of the signal S input from the first sensing unit 40 and the second sensing unit 50 changes. And a control unit (60) for outputting a signal judged to be a data line abnormality detection circuit of the multi-drop communication circuit. The data line abnormality detection circuit of claim 1, further comprising a comparator (70) between the switching unit (20) and the first sensing unit (40). The method of claim 2, wherein the comparator 70 comprises a comparator 72 for inverting and outputting the input signal by comparison with a reference voltage after the input signal is input to the inverting terminal to the switching unit 20. Data line abnormality detection circuit of multi-drop communication circuit. The data line abnormality of the multi-drop communication circuit of claim 1, wherein the switching unit 20 comprises a relay element connected to and disconnected from the data line with respect to the interface 10 under the control of the switching control unit 30. Sensing circuit. The multi-drop communication circuit of claim 1, wherein when the malfunctioning signal is output by the controller 60, the switching controller 30 separates the switching unit 20 from an external data communication line. Data line fault detection circuit. The data receiver 40A is an inverter 42 for receiving and inverting an output signal from the comparator 70 and inputs a signal output from the inverter 42 to the controller 60. ,
The first sensing unit 40 is connected to the output terminal of the comparator 70 and consists of an inverter 46 connected via a diode 44 and inputs a signal output from the inverter 46 to the controller 60. And a data line abnormality detection circuit of the multi-drop communication circuit. The inverter 50, the diode 52, and the inverter 53 are sequentially connected in order to receive data from the controller 60 and output the data to the switching unit 20. The base is connected to the first transistor 54 having a resistor R1 connected to the base and the emitter grounded, the resistor R2 connected to the collector of the first transistor 54 and a resistor R3 between the base and the emitter. ) Is connected to the power supply terminal, the second transistor 55 having the diode 56 connected to the collector, the collector connected to the diode 56, and the base connected via the resistor R4 to the inverter 51. And the emitter is composed of a third transistor 57 having an emitter grounded, and a connection point of the collector of the third transistor 57 and the diode 56 is connected to the switching unit 20. Data line error detection circuit of communication circuit. The high signal (H) is normally input by the control part 60 to the input side of the inverter 53 of the data transmission part 50A,
The second detector 50 includes a diode 58 connected to the collector of the second transistor 55 and an inverter 59 connected to the diode 58. Circuit. The switching controller 30 of claim 1, wherein the controller 60 is connected to the switching controller 30, the data receiving unit 40A, the first sensing unit 40, and the data transmitting unit 50A, and is usually made of an oscillation element. ) To allow oscillation to be made so that the data communication line is connected to the switching unit 20 made of a relay element, and when the signal determined to be malfunction by the control unit 60 is output, the switching control unit 30 causes the oscillation. And stop the data communication line with respect to the switching unit (20). The method of claim 7, wherein the same high signal (H) is normally output from the first and second detectors 40 and 50, and in case of malfunction, the first and second detectors 40 and 50. The data line abnormality detection circuit of the multi-drop communication circuit, wherein at least one output signal of 50) is outputted with a low signal (L). The method of claim 7, wherein the signals of the output terminals B and C of the first and second sensing units 40 and 50 connected to the control unit 60 are initially high when both signals are initially high. If at least one of these output stages B, C changes to low L during the time, at least one of the first to third transistors 54, 55, 57 of the data line or the data transmitter 50A has a problem. The controller 60 outputs a signal determined to be generated,
As a result, the switching controller 30 causes the switching unit 20 to separate an external data line. The controller of claim 11, wherein the high signal H is output to the output terminal B of the first sensing unit 40, and the low signal L is output to the output terminal C of the second sensing unit 50. 60 is a data line abnormality detection circuit of the multi-drop communication circuit, characterized in that for outputting a signal that the first transistor (54) or the second transistor (55) is bad. 12. The low signal L is output to the output terminal B of the first sensing unit 40 before the switching unit 20 disconnects the connection with the data line by the control unit 60. The high signal H is output to the output terminal C of the sensing unit 50, and then after the switching unit 20 disconnects the connection with the data line by the control unit 60, the first sensing unit 40 is removed. When the low signal L is output to the output terminal B of the output signal C and the high signal H is output to the output terminal C of the second detector 50, the controller 60 indicates that the third transistor 57 is defective. A data line abnormality detection circuit of a multi-drop communication circuit, characterized by outputting a signal. The low signal L is output to the output terminal B of the first sensing unit 40 before the switching unit 20 disconnects the connection to the external data line by the control unit 60. The high signal H is output to the output terminal C of the second sensing unit 50. After that, the switching unit 20 disconnects the connection with the external data line by the control unit 60, and then the first sensing unit ( When the high signal (H) is output to the output terminal (B) of 40 and the high signal (H) is output to the output terminal (C) of the second sensing unit (50), the controller 60 indicates that the external data line is defective. A data line abnormality detection circuit of a multi-drop communication circuit, characterized by outputting a signal.

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