KR0118639Y1 - Digital input detector with self diagnostic function - Google Patents

Abstract

The present invention relates to a digital input circuit having a self-diagnosis function. The conventional circuit and the modified example of the conventional circuit have only a function of discriminating only the high or low signal of the digital input, so that the input signal is actually being processed off due to a failure of the device. There was a problem that could not be prevented.

In order to solve the problems of the conventional circuit, the present invention outputs a high and low signal value of a digital input separately, and a digital input detection circuit having a self-diagnosis function for preventing misunderstanding of input data due to a failure of a circuit element is proposed. will be.

Description

Digital Input Detection Circuit with Self Diagnosis

1 is a conventional digital input detection circuit diagram.

2 is a circuit diagram of a modification of a conventional digital input detection circuit.

3 is a digital input detection circuit having a self-diagnostic function of the present invention.

4 is an output state diagram of each terminal of the digital input detection circuit having a self-diagnostic function of the present invention.

* Explanation of symbols for main parts of the drawings

1, 3, 4, 10-13: Photocoupler 2: Inverter

5, 16, 17: pulse signal detector 18: normal operation discriminating unit

PSI: Pulse Signal Source

The present invention relates to a digital data input circuit, and more particularly, to a digital input detection circuit having a self-diagnosis function that prevents error data from being input by judging whether a failure or malfunction of the input detection circuit occurs.

In the conventional digital input detection circuit, as shown in FIG. 1, the input terminal Din1 is connected to another input terminal Din2 through a resistor R1 and a photocoupler 1 diode D1, and a photocoupler. (1) The transistor Q1 emitter is grounded and the collector is configured to be connected to the power supply voltage VCC via a resistor R1 and to the output terminal Dout1 via an inverter 2.

As shown in FIG. 2, the conventional digital input detection circuit is modified, and the input terminal Din3 is connected through the resistor R1 and the photocoupler 4 diode D4 and the transistor Q3 of the photocoupler 3. Connected to another input terminal (Din4), across the diode (D3) of the photocoupler (3) is connected to the pulse signal input (PSI), the photocoupler (4) transistor (Q4) emitter is grounded and the collector is a resistor It is configured to be connected to the power supply voltage (VCC) through (R2) and to the output terminal (Dout2) through the signal detector (5).

The operation of the conventional circuit is described in detail with reference to FIG. 1 as follows.

When a high signal is input to the input terminals Din1 and Din2, current flows into the diode D1 of the photocoupler 1, the transistor Q1 is turned on, and a low signal is applied to the input terminal of the inverter 2, so that the inverter ( 2) outputs a high signal to the output terminal Dout1. On the other hand, when a low signal is input to the input terminals Din1 and Din2, the transistor Q1 is also blocked when no current flows into the diode D1 of the photocoupler 1. When the transistor Q1 is cut off, an input of high is applied to the inverter 2, and the inverter 2 applies an output of low to the output terminal Dout1.

Referring to FIG. 2, the operation of the conventional circuit modification is as follows.

When a high signal is input to the input terminals Din3 and Din4, the input current flows through the photocoupler 4 diode D4 and the photocoupler 3 transistor Q3. At this time, when the pulse signal source RSI applies the pulse signal to the photocoupler 3 diode D3, the diode D3 is continuously turned on and off, and thus the transistor Q3 is continuously turned off. The photocoupler 4 diode D4, which is connected to the transistor Q3 of the photocoupler 3, is repeatedly turned off when the transistor Q3 is turned on and turned on when the transistor Q3 is turned off. As described above, when the diode D4 of the photocoupler 4 continues the on-off operation, the transistor Q4 also continues the on-off operation to input a continuous pulse to the pulse signal detector 5. This pulse signal detector 5 detects that a continuous pulse is input and outputs high to the output terminal Dout2.

On the other hand, when a low signal is applied to the input terminals Din3 and Din4, the photocoupler 4 diode D4 is turned off, and as a result, the transistor Q4 is continuously turned off, and thus the pulse generated from the pulse signal source PSI is generated. Since the signal is not transmitted to the pulse signal detector 5, the pulse signal detector 5 outputs a low signal to the output terminal Dout2.

However, the conventional circuit and the modified example of the conventional circuit configured as described above have only a function of discriminating only the high or low signal of the digital input, and there is a problem in that the input signal is actually prevented from being turned off due to a failure of the device.

In order to solve the problems of the conventional circuit, the present invention outputs a high and low signal value of a digital input separately, and a digital input detection circuit having a self-diagnosis function for preventing misunderstanding of input data due to a failure of a circuit element is proposed. It will be described in detail below with reference to the accompanying drawings.

As shown in FIG. 3, the digital input circuit having the self-diagnosis function of the present invention has a high signal detection unit that outputs a pulse generated from a pulse signal source PSI when a high signal is input from the input terminals Din5 and Din6. (14), a low signal detector 15 for outputting a pulse generated from a pulse signal source PSI when a low signal is input from the input terminals Din5 and Din6, and a pulse is input from the high signal detector 14; If the pulse signal detector 16 applies a high signal to the high output terminal Hout, and the pulse signal detector 17 applies a high signal to the low output terminal Lout when a pulse is input from the low signal detector 15. ) And a signal input from the high output terminal Hout of the pulse signal detector 16 and the low output terminal Lout of the pulse signal detector 17 are different from each other, the input terminal Din5 to the input data output terminal Dout3. , Same as the signal input from Din6) At the same time, a high signal indicating normal operation of the circuit is output to the normal operation output terminal CNout, and when the signals input from the high output terminal Hout and the low output terminal Lout are the same, the normal operation output terminal ( And a normal operation discriminating unit 18 for outputting a low signal indicating a malfunction of the circuit to CNout. The high signal detecting unit 14 includes a diode 10 receiving a signal from an input terminal through a resistor R1; The emitter is grounded and the collector is coupled with a photocoupler 10 and a diode D12, including a transistor (Q10) connected at one end of the resistor (R2) connected to the supply voltage (VCC) and the input of the pulse signal detector (16). The photocoupler 11 includes a diode D11 connected in series to a pulse signal source PSI and a transistor Q11 connected in parallel to the diode D10, and the low signal detection unit 15 includes a diode D11. With non-woven The diode (D12) and the emitter connected to the low pulse signal source (PSI) are grounded, and the collector is connected to the connection point between the resistor (R3) connected to the power supply voltage (VCC) and the input of the pulse signal detector (17). The photocoupler 12 and the anode are connected to the connection point of the cathode of the diode D10 and the emitter of the transistor Q11 and the cathode is in parallel with the diode D13 and the diode D12 connected to the input terminal Din6. And a photocoupler 13 including transistors Q13 connected to each other.

If described in detail with reference to Figure 3 and Figure 4 the effect of the present invention circuit.

In the first case, when a high signal is input to the input terminals Din5 and Din6, the input current flows through the diode D10 of the photocoupler 10 and the transistor Q11 of the photocoupler 11. At this time, when a pulse signal is applied to the diode D11 of the photocoupler 11 from the pulse signal source PSI, the diode D11 continues to be turned on and off in accordance with this signal. When the diode D11 performs the on-off operation continuously, the transistor Q11 also performs the on-off operation continuously. When the transistor Q11 is turned on, the photocoupler 10 diode D10 connected in parallel thereto is turned off. When the transistor Q11 is turned off, the diode D10 is turned on. As described above, when the diode D10 continues the on-off operation, the transistor Q10 of the photocoupler 10 is also turned on and off. As a result, the pulse signal output from the pulse signal source PSI is output through the transistor Q10 of this photocoupler 10. When a pulse continuously output from the collector of the transistor Q10 is input to the pulse signal detector 16, the pulse signal detector 16 outputs a high signal to the high output terminal Hout. On the other hand, when the current flowing through the diode D10 of the photocoupler 10 or the transistor Q11 of the photocoupler 11 flows back to the photocoupler 13 diode D13, the transistor Q13 becomes conductive. When the transistor Q13 is turned on, the diode D12 of the photocoupler 12 is turned off so that the transistor Q12 is cut off accordingly. Since the transistor Q12 of the photocoupler 12 is continuously in a blocking state, no pulse is input to the pulse signal detector 17, so the pulse signal detector 17 outputs a low output terminal Lout low. . In this way, the high signal is applied to the high output terminal Hout and the low signal is applied to the low output terminal Lout. Outputs a high signal indicating normal operation of the circuit to the normal operation output terminal CNout.

In the second case, when a low signal is input to the input terminals Din5 and Din6, since there is no input current, the photocoupler 10 diode D10 is turned off. Accordingly, the transistor Q10 is turned off and output from the pulse signal source PSI. The pulse to be inputted is not input to the pulse signal detector 16. Accordingly, the pulse signal detector 16 outputs a low signal to the high output terminal Hout. On the other hand, since the diode D10 is turned off because no current flows from the input terminal, the diode D13 of the photocoupler 13 connected in series is also turned off and thus the transistor Q13 is turned off. Since the transistor Q13 remains in the OFF state, the diode D12 of the photocoupler 12 connected in series with the pulse signal source PSI through the diode D11 is outputted from the pulse signal source PSI. Continues the on-off operation according to the pulse. The transistor D12 of the photocoupler 12 continues the on-off operation, and the transistor Q12 also continues the on-off operation, and outputs a continuous pulse to the pulse signal detector 17 through the collector. The pulse signal detector 17 applies a high signal to the low output terminal Lout because a continuous pulse is input to the input terminal. In this way, since the low signal is applied to the high output terminal Hout and the high signal is applied to the low output terminal Lout, the normal operation discrimination unit 18 has a low signal at the input data output terminal Dout3 as shown in FIG. Outputs a high signal indicating normal operation of the circuit to the normal operation output terminal CNout.

In the third case, when a circuit element fails, assuming that a failure occurs in the pulse signal source PSI, the diodes D11 and D12 connected in series with the pulse signal source PSI are turned off. As a result, the transistors Q11 and Q12 are turned off so that the photocouplers 11 and 12 do not operate. If the photocoupler 11 does not operate, the photocoupler 10 connected thereto does not output the pulse signal to the pulse signal detector 16 through the collector of the transistor Q10. Output low signal to output terminal (Hout). Similarly, since the transistor Q12 of the photocoupler 12 is also in the off state, no pulse signal is input to the pulse signal detector 17, so the pulse signal detector 17 outputs a low signal to the low output terminal Lout. Thus, since the low signal is applied to the high output terminal Hout and the low signal is applied to the low output terminal Lout, the normal operation discriminating unit 18 is connected to the normal operation output terminal CNout as shown in FIG. Outputs a low signal indicating malfunction.

In the fourth case, when a high signal is input to the input terminals Din5 and Din6, and a failure occurs in the transistor Q10 of the photocoupler 10, the pulse is not outputted to the pulse signal detector 16 so that the pulse signal detector ( 16 outputs a low signal to the high output terminal Hout. On the other hand, when the current flows from the input terminal and the diode D13 of the photocoupler 13 is conducted, the transistor Q13 is turned on. When the transistor Q13 is turned on, the diode D12 of the photocoupler 12 is turned off and the transistor is turned off. Q12 is turned off. Therefore, since no pulse signal is input from the port coupler 12 to the pulse signal detector 17, the pulse signal detector 17 outputs a low signal to the low output terminal Lout. Since a low signal is applied to the high output terminal Hout and a low signal is applied to the low output terminal Lout as described above, the normal operation determiner 18 outputs a low signal indicating a malfunction of the circuit as shown in FIG. do.

In the fifth case, when a failure occurs in the photocoupler 12 and a low signal is input to the input terminals Din5 and Din6, the input current does not flow, so the diode D10 of the photocoupler 10 is turned off and the transistor Q10 Is turned off so that the pulse signal is not output to the pulse signal detector 16, so that the pulse signal detector 16 outputs a low signal to the high output terminal Hout. On the other hand, since a failure occurs in the photocoupler 12, the pulse signal detector 17 cannot output a pulse, so the pulse signal detector 17 outputs a low signal to the low output terminal Lout. Since a low signal is applied to the high output terminal Hout and a low signal is applied to the low output terminal Lout as described above, the normal operation determiner 18 outputs a low signal indicating a malfunction of the circuit as shown in FIG. do.

In this way, when the circuit of the present invention is used, data misreading caused by a failure of a circuit element is prevented when processing digital input data.

Claims (3)

The high signal detector 14 outputs a pulse generated from the pulse signal source PSI when a high signal is input from the input terminals Din5 and Din6, and the pulse signal source when a low signal is input from the input terminals Din5 and Din6. A low signal detector 15 for outputting a pulse generated from the PSI, a pulse signal detector 16 for applying a high signal to the high output terminal Hout when a pulse is input from the high signal detector 14, When a pulse is input from the low signal detector 15, a pulse signal detector 17 for applying a high signal to the low output terminal Lout, and a high output terminal Hout and a pulse signal detector of the pulse signal detector 16. If the signals input from the low output terminal (Lout) of (17) are different from each other, the same signal as the signal input from the input terminals (Din5, Din6) is output to the input data output terminal (Dout3) and the normal operation output terminal (CNout) Indicates the normal operation of the circuit. The normal operation discrimination unit outputs a high signal and outputs a low signal indicating a malfunction of the circuit to the normal operation output terminal CNout when the signals input from the low output terminal Lout to the high output terminal Hout are the same. Digital input detection circuit having a self-diagnostic function, characterized in that consisting of 18). The resistor (R2) of claim 1, wherein the high signal detector (14) receives a signal from an input terminal through a resistor (R1) and the emitter is grounded and the collector is connected to a power supply voltage (VCC). Diode D11 and diode D10 connected in series with the pulse signal source PSI together with the photocoupler 10 and diode D12 connected to the junction of the input signal and the pulse signal detector 16 input terminal. A digital input detection circuit having a self-diagnosis function, comprising a photocoupler (11) including a transistor (Q11) connected in parallel to the circuit. The diode D12 and the emitter of the low signal detector 15 connected to the pulse signal source PSI in series with the diode D11 are grounded, and one end of the collector is connected to the power supply voltage VCC. The photocoupler 12 and anode comprising a transistor Q12 connected to a connection point of the resistor R3 and the pulse signal detector 17 input terminal are connected to the connection point of the cathode of the diode D10 and the emitter of the transistor Q11. And the cathode comprises a diode (D13) connected to an input terminal (Din6) and a photocoupler (13) including a transistor (Q13) connected in parallel with the diode (D12).