KR200195844Y1 - Commuication apparatus between checking apparatus and electronic control unit - Google Patents

Abstract

Communication device between the control unit and the electronic control unit that transmits / receives data through the K line when the L line is in the “high” state, and sends information of the fault signal to the same port when the L line is in the “high” state. The first and second filtering means for removing various kinds of noise introduced from the outside, the first voltage dividing means for dividing the potential of the signal output from the K line and outputting a signal of a constant potential, and the first partial pressure First switching means switched in accordance with the signal of the means, second switching means switched in accordance with the signal of the first switching means, signal inverting means for inverting the signal output from the data transmitting end, and signal of the signal inverting means The third switching means switched according to the signal, the fourth switching means switched according to the signal of the data transmitting end, and the switch according to the signal of the fourth switching means. And a second voltage dividing means for dividing the signal of the fifth switching means. The L line maintains high when communicating and maintains low when outputting a fault signal. By using the K line data transmitter, K line communication and fault signal output can be used so that only 5 CPU ports can be used.

Description

Communication device between inspection device and electronic control device

The present invention relates to a communication device between the inspection device and the electronic control device. More specifically, when the L line is in the "high" state, data is transmitted and received through the K line, and in the "low" state, the same port fails. The present invention relates to a communication device between an inspection device and an electronic control device that sends a signal output to provide information to a driver.

In general, the communication between the electronic control device and the inspection device is to perform data communication through the communication cable line in accordance with the GST protocol.

The data communication is installed at an arbitrary position in the vehicle to detect the failure of the vehicle and receive the contents stored in the electronic control device as mutually promised data through the input / output device as shown in FIG. Users and maintenance workers can see the presence of the naked eye so that the maintenance of the exact failure site can be done easily.

However, in the conventional apparatus as shown in FIG. 2, since six communication ports are used to configure communication-related circuits, in order to add necessary functions in the future, CPU replacement or circuit redesign is inevitable and there is a problem of insufficient memory. .

The present invention is to solve such a problem, the purpose of the line is to maintain the "high" when communicating the characteristics of the L line, and "low" when outputting the fault signal by using the transmission line of the K line to the K line communication It also serves as a fault output signal output so that only five CPU ports can be used.

In order to achieve the above object, the present invention is a communication device between the inspection device and the electronic control device, the L line signal transmission unit for holding a predetermined signal according to the connector connection of the L line, and the K line and the failure One side is connected to the signal output terminal, the other side is grounded to the case, and the first and second filtering means for removing various noises from the outside, and connected to the K line by dividing the potential of the signal output through the K line A first voltage dividing means for outputting a signal of a potential and a first switching means connected to the first voltage dividing means and switched according to a signal of the first voltage dividing means, and connected to the first switching means to a signal of the first switching means. Signal inverting means connected to the second switching means and the data transmitting end switched according to the inverted signal output from the data transmitting end, and one end of the Third switching means connected to the signal inverting means and the other end connected to the first voltage dividing means and switched according to the signal of the signal inverting means, and fourth switching means connected to the data transmitting end and switched according to the signal of the data transmitting end. And fifth dividing means connected to the fourth switching means and switched according to a signal of the fourth switching means, and second dividing means connected to the fifth switching means to divide the signal of the fifth switching means. It is characterized by.

1 is a detailed circuit diagram showing an embodiment according to the communication device between the inspection device and the electronic control device of the present invention,

2 is a detailed circuit diagram showing a communication device between the conventional inspection device and the electronic control device.

* Explanation of symbols for main parts of the drawings

20, 90: voltage divider 30: first switching unit

40: second switching unit 50: inverter

60: third switching unit 70: fourth switching unit

80: fifth switching unit C10, C100: first, second filter

Hereinafter, a preferred embodiment according to the present invention with reference to the accompanying drawings as follows.

As can be seen in FIG. 1, a preferred embodiment of the present invention includes an L-line signal transmission unit C1, C2, D1, D2, R1, R2, 1, a first filter C10, and a second filter ( C100), the first voltage dividing unit 20, the second voltage dividing unit 90, the first, second, third, fourth, and fifth switching units 30, 40, 60, 70, and 80, and the inverter 50 )

The L line signal transmission unit has one side grounded to the case and the other side connected to the capacitor C1 connected to the checker L line, the anode end of which is connected to the diode (D2), and the anode end of which is connected to the cathode of the diode (D2). A constant voltage unit configured to keep the output signal of the L line at a constant potential, which is composed of a diode D1 connected in parallel with the capacitor C1 on the L line, and a power terminal V5 is connected to one side, and the other end is a cathode terminal of the diode B2. One side of the pull-up resistor (R1), which outputs a signal of "high" when there is no connector connection of L line and outputs a signal of "low" when there is a connector connection of L line, is connected to a diode (D2). Capacitor (C2) connected to the cathode end of the circuit and removes noise present in the signal of the pull-up resistor (R1), the input terminal is connected to the other side of the capacitor (C2), and the output terminal is connected to the electronic control field through the resistor (R2). Is connected to the receiving end comprises a drive (1) to be applied to the receiver by inverting the signal of the pull-up resistor (R1).

One end of the first filter C10 is grounded to the case, and the other end of the first filter C10 is connected to the K line to remove various noises introduced from the outside.

The first voltage dividing unit 20 is connected to the Zener diode ZD rounded with a resistor R21 and the anode terminal in parallel, and divides the potential of the signal output from the K line to the Zener diode ZD which is a constant voltage diode. This outputs a signal with a constant electric potential.

In the first switching unit 30, a voltage divider and an emitter stage in which the resistor R31 and the resistor R32 are connected in parallel are connected to the power supply terminal V, and a diode D and a capacitor ( C33 is formed of a PNP transistor TR34 connected in parallel, and is switched according to the signal of the first voltage dividing unit 20 to output a predetermined signal.

The second switching unit 40 has a base end connected to the first switching unit 30 through a resistor R41 and a collector end connected to the power supply terminal V through one pull-up resistor R44. It is connected to the receiving end and the emitter stage is grounded, the emitter stage and the base stage is composed of NPN transistor TR43 connected via a resistor (R42), it is switched in accordance with the signal of the first switching unit 30 accordingly Output a predetermined signal.

The inverter 50 inverts and outputs the signal output from the data transmission end.

The third switching unit 60 has a base end connected to the inverter 50 through a voltage divider in which a resistor R61 and a resistor R62 are connected in parallel, an emitter end is grounded, and a collector end is connected to the first voltage divider. An NPN transistor TR63 connected to the connection terminal 20 and the first switching unit 30 is switched according to the signal of the inverter 50 to output a predetermined signal.

The fourth switching unit 70 includes an NPN transistor TR73 having a base end connected to a data transmitting end through a resistor R71, and a base end and a collector end connected to a resistor R72, according to a signal of the data transmitting end. It is switched to output a predetermined signal accordingly.

The fifth switching unit 80 has a base terminal connected to the collector terminal of the fourth switching unit 70 NPN transistor TR73 through the resistor R81, and the emitter terminal is connected to the power supply terminal V, The terminal and base are formed of a PNP transistor TR83 connected by a resistor R82, and are switched according to the signal of the fourth switching unit 70 to output a predetermined signal.

In the second voltage dividing unit 90, a resistor R91 and a resistor R92 are connected in parallel to each other and connected to the collector terminal of the fifth switching unit 80 and the PNP transistor TR83, and the fifth switching unit 80. ) The signal potential is divided and output.

One end of the second filter C100 is grounded to the case, and the other end of the second filter C100 is connected to the L line to remove various noises introduced from the outside.

Referring to the preferred embodiment according to the present invention configured as described above in detail according to the operation process as follows.

During communication between the fault check device and the electronic control device, if a connector is connected to the check device L line and outputs a “low” signal, the receiving end of the electronic control device is operated by the operation of the pull-up resistor R1 and the inverter 1. If the signal of “High” is maintained and the signal of “High” is output because there is no connector connection on the check device L line when the fault signal is output, the receiving terminal of the electronic control device is operated by the pull-up resistor (R1) and the operation of the inverter (1). Maintains a low signal.

When the L line maintains "high" and communicates When the K line transmits data, when the K line outputs a predetermined signal, that is, for example, outputs a "high" signal, the first voltage divider ( At 20), the potential of the signal is divided and output as a signal of a constant potential by the zener diode ZD which is a constant voltage diode.

At this time, the first filter C10 removes various noises introduced from the outside.

Then, when the signal of the first voltage dividing unit 20 is applied to the base terminal of the PNP transistor TR34 of the first switching unit 30 through a voltage divider in which the resistor R31 and the resistor R32 are connected in parallel, the first switching is performed. The base end of the PNP transistor TR34 of the section 30 is switched off while maintaining a high potential.

At the same time, since the NPN transistor TR43 of the second switching unit 40 is also turned off, the second switching unit 40 outputs a “high” signal by the pull-up resistor R44 connected at one end thereof to the power supply terminal V. To the data receiver.

In addition, when the K line outputs a "low" signal, a "low" signal is applied to the data receiver to transmit the data signal.

Contrary to the above, when the L line maintains high and the K line receives the data signal, when the data transmitter outputs the signal “high”, the inverter 50 inverts the signal output from the data transmitter to “low”. Signal is output.

Then, the third switching unit 60 maintains the switching state of the NPN transistor TR63 by the “low” signal of the inverter 50 applied through the voltage divider connected in parallel with the resistor R61 and the resistor R62. Therefore, the K line remains “high”.

Unlike the above, when the data transmitter outputs a signal of "low", the NPN transistor TR63 is switched on in accordance with the above operation, so that the K line maintains a signal of "low".

Therefore, the K line receives the signal of the data transmitting end by the above operation.

However, in the case where the L line maintains "low" and outputs a fault signal, when the fault signal is output from the data transmitter, for example, a "high" signal is output, the NPN transistor TR73 of the fourth switching unit 70 is output. Is switched on and outputs a “high” signal.

At the same time, since a low potential is formed at the base terminal of the PNP transistor TR83 of the fifth switching unit 80, the second voltage divider unit is configured to switch on a signal of “high” in parallel with the resistors R91 and R92. It is applied to the fault signal output terminal through 90.

In this case, the second filter C100 removes various noises introduced from the outside.

Even when the data transmitting end outputs a "low" signal, the "low" signal is output to the fault signal output end by the above operation.

As such, the present invention utilizes the characteristics of the L line, which maintains "high" during communication and "low" when outputting a fault signal, so that the data transmission terminal of the K line also serves as the K line communication and fault signal output. Allow only five ports to be used.

Claims (7)

In the communication device between the inspection device and the electronic control device, one end is connected to the L line signal transmission unit for receiving a predetermined signal according to the connector of the L line, and one end is connected to the K line and the fault signal output end, and the other side is connected to the case. First and second filtering means which are grounded to remove various noises introduced from the outside, first dividing means connected to the K line to divide the potential of the signal output through the K line and output a signal having a constant potential; First switching means connected to the first voltage dividing means and switched according to a signal of the first voltage dividing means, second switching means connected to the first switching means and switched according to the signal of the first switching means, and a data transmitting end; Signal inverting means for inverting a signal output from a data transmitting end connected to the first end, and one end of which is connected to the signal inverting means and the other end of the first Third switching means connected to the pressure means and switched according to the signal of the signal inversion means, fourth switching means connected to the data transmission end and switched according to the signal of the data transmission end, and fourth connected to the fourth switching means. And a fifth dividing means switched according to a signal of the switching means, and a second dividing means connected to the fifth switching means to divide the signal of the fifth switching means. Device. The communication device according to claim 1, wherein the first voltage dividing means is connected in parallel with a resistor (R21) and a Zener diode (ZD) having an anode terminal grounded in parallel. The method of claim 1, wherein the first switching means includes a voltage divider connected in parallel with a resistor (R31) and a resistor (R32), the emitter stage is connected to the power supply terminal (V), and the diode (D) at the base stage and the emitter stage. ) And a communication device between the control device and the electronic control device, characterized in that the capacitor (C33) is made of a PNP transistor (TR34) connected in parallel. The method of claim 1, wherein the second switching means has a base end connected to the first switching means via a resistor (R41), the collector end is connected via a pull-up resistor (R44), one end is connected to the power supply terminal (V). And an NPN transistor (TR43) connected to the receiving end, the emitter end being grounded, and the emitter end and the base end connected via a resistor (R42). The method according to claim 1, wherein the third switching means is connected to the signal conversion means, the emitter stage is grounded, the collector stage is connected to the first stage through the voltage divider connected in parallel with the resistor R61 and the resistor R62 And a NPN transistor (TR63) connected to the connection terminal of the voltage dividing means and the first switching means. The inspection apparatus according to claim 1, wherein the fourth switching means comprises an NPN transistor TR73 having a base end connected to a data transmitting end via a resistor R71 and a base end and a collector end connected to a resistor R72. And communication device between the electronic control unit. The method of claim 1, wherein the fifth switching means has a base end connected to the fourth switching means through a resistor (R81), the emitter end is connected to the power supply terminal (V), the emitter stage and the base end is a resistor (R82) Communication device between the control device and the electronic control device, characterized in that consisting of a PNP transistor (TR83) connected to.