CS236196B1 - Input circuit connection with optoelectronic coupler - Google Patents

Abstract

Control input comes to input terminals current. In one of its polarities, it lights first electroluminescent diode and closes current in the circuit of the first photodiode. At first the resistance is generated by the voltage drop that is being applied to an inverting differential input amplifiers. On the non-inverting input of the amplifier is potential country. Differential Amplifier Output is a level of 10 g 0. When it comes to input terminals control current of opposite polarity works the same way the other optoelectronic coupling and differential output amplifier is level log. 1.

Description

The invention relates to the connection of an input circuit with an optoelectronic coupler in a digital information transmission device.

The purpose of optoelectronic couplers is to galvanically isolate some devices or parts thereof. When transmitting digital information, the emitting electroluminescent diode, which in turn optically controls the receiving phototransistor or photodiode, lights up and goes out in the rhythm of the digital signals. Therefore, binary information is transmitted - it is lit, it is not lit.

The known circuit of an input circuit with an optoelectronic coupler has an anti-parallel diode connected to the emitting diode. These diodes should preferably have the same voltage-current characteristic. In one direction of the control current, the current is closed via a transmitting electroluminescent diode. In the inverse direction of the control current, the current is closed via an anti-parallel connected diode, thereby accelerating the discharge of the line capacity. The potential in the receiving portion of the optoelectronic coupler is connected in the reverse direction parallel to the first resistor of the voltage divider, the center of which is connected to the inverting input of a differential amplifier powered by a symmetrical voltage. The non-inverting input of the differential amplifier is connected to ground. The voltage divider sets the potential at the inverting input of the differential amplifier to + V when the optoelectronic coupler is closed. When the photodiode is illuminated, its resistance decreases and the potential on the inverting input of the differential amplifier decreases ·

- 2 - 238 198 to -V. The differential amplifier receives the opposite excitation and the logic level changes at its output. A disadvantage of the known circuitry is that due to the required symmetry of the excitation and the symmetry of the capacitance of the line, several antiparallel connected diodes need to be connected in series in order to achieve the same voltage-current characteristic as possible. For physical reasons, electroluminescent diodes have different voltage current characteristics than ordinary diodes. Another disadvantage is the necessity of individually energizing the voltage divider. The set input voltage of the differential amplifier may vary due to variations in symmetrical supply voltages or variations in photodiode resistance due to changes in current passing through the emitting diode. '

The purpose of the invention is to overcome these disadvantages. According to the principle of the invention, this is achieved by connecting to the first input terminal the cathode of the first electroluminescent diode of the first optoelectronic coupler and the anode of the second electroluminescent diode of the second optoelectronic coupler. The anode of the first electroluminescent diode of the first optoelectronic coupler and the cathode of the second electroluminescent diode of the second optoelectronic coupler are connected to the second input terminal. The cathode of the first photodiode of the first optoelectronic coupler is connected to the positive terminal of the source and the anode of the first photodiode is coupled via the first resistor to ground and to the inverting input of the differential amplifier. The cathode of the second photodiode of the second optoelectronic coupler is connected to the positive terminal of the source and the anode of the second photodiode is connected via a second resistor to the ground and to the non-inverting input of the differential amplifier whose power is symmetrical from the positive and negative terminals of the source.

The advantage of the circuitry according to the invention is that the excitation current is sufficiently symmetrical since both electroluminescent diodes are of the same type. There is no need to adjust the input voltage of the differential amplifier. Although photodiodes with different resistances may occur in the illuminated, i.e. non-conductive state, in the wiring operation, the resistance of the second photodiode in the non-illuminated, i.e. non-conductive, state prevails.

An example of a circuit of an input circuit with an optoelectronic coupler according to the invention is further described with reference to the drawing.

236 196

To the first input terminal 1, the cathode of the first electroluminescent diode ED1 of the first optoelectronic coupler 01 and the anode of the second electroluminescent diode ED2 of the second optoelectronic coupler 02 are connected. Anode of the first electroluminescence diode EDI and the cathode of the second electroluminescent diode2 . The cathode of the first photodiode FD1 of the first optoelectronic coupler 01 is connected to the positive terminal + U of the source. The cathode of the second photodiode FD2 of the second optoelectronic coupler 02 is connected to the positive terminal + U of the source. The anode of the first photodiode FD1 is connected through the first resistor R1 to ground and to the inverting input J of the differential amplifier Z. The anode of the second photodiode FD2 is connected through the second resistor R2 to the ground and to the non-inverting input 4 of the differential amplifier Z with the output terminal. The power supply for the differential amplifier Z is symmetrical from the positive and negative terminals of the + U, -U power supply.

A control current of such polarity is applied to the input terminals 1, 2 that the first electroluminescent diode EDI of the first optoelectronic coupler 01 is in a conductive illuminated state. The current is closed in the circuit of the first photodiode FD1 as follows: positive terminal + U source, cathode of the first photodiode FD1, anode of the first photodiode FD1, first resistor R1, ground. A voltage drop occurs at the first resistor R1, which is determined by the value of the first resistor R1 and the current flow rate. The positive potential thus generated is applied to the inverting input J of the differential amplifier Z. At the non-inverting input 4 of the differential amplifier Z is the ground potential. At the output of the differential amplifier Z there is a log level of 0. If the input control current of opposite polarity is applied to the input terminals 1, 2, the second optoelectronic coupler 02 operates in the same way and at the output 2 of the differential amplifier Z there is a log level.

The circuitry according to the invention can be used to transmit high-speed digital signals due to its symmetry and using elements of sufficiently short transmission time.

Claims (1)

Connection of an input circuit with an optoelectronic coupler in a digital information transmission device with a differential amplifier, characterized in that a first electroluminescent diode (EDI) cathode of the first optoelectronic coupler (01) and an anode of the second electroluminescent diode are connected to the first input terminal (1). (ED2) of the second optoelectronic coupler (02) while the anode of the first electroluminescence diode (EDI) of the first optoelectronic coupler (01) and the cathode of the second electroluminescent diode (ED2) of the second optoelectronic coupler (02) are connected to the second input terminal (2). ), the cathode of the first photodiode (FD1) of the first optoelectronic coupler (01) is connected to the positive terminal (+ U) of the source and the anode of the first photodiode (FD1) is connected via the first resistor (R1) to ground and inverting input (3) differential amplifier (Z), while the cathode of the second photodiode (FD2) of the second optoelectronic coupler (02). it is connected to the positive terminal (+ U) of the source and the anode of the second photodiode (FD2) is connected through the second resistor (R2), to ground and to the non-inverting input (4) of the differential amplifier (Z) whose power is symmetrical from the positive and negative terminals (+ U, -U) resources.