KR102615571B1 - Apparatus for compensating failure of mcu for vehicle lamp - Google Patents

Abstract

The present invention relates to a fault compensation device for MC oil for vehicle lamps, comprising: a regulator that generates a signal that can be applied as a driving signal to a lamp driver; A pulse detection unit that detects a pulse signal output when an MCU (Micro Control Unit) that applies a driving signal to the lamp driver is in a normal state; And a first unit that receives a signal output from the regulator, switches on and off depending on whether the pulse signal output from the MCU is detected through the pulse detection unit, and outputs or blocks the signal generated by the regulator to the lamp driver. Includes a switching unit.

Description

MCU's failure compensation device for vehicle lamps {APPARATUS FOR COMPENSATING FAILURE OF MCU FOR VEHICLE LAMP}

The present invention relates to a malfunction compensation device for MCU for vehicle lamps. More specifically, the present invention relates to a malfunction compensation device for MCU (MCU) that controls the lamp driver that supplies power to vehicle lamps by detecting a failure and applying a driving signal to the lamp driver. , relates to a fault compensation device for MCU for vehicle lamps, which prevents unintentional lamp off by the user.

In general, various lamps (or lights) are installed in vehicles. These lamps include headlamps, fog lamps, tail lamps, turn signal lamps, and stop lamps. Recently, LED lamps are widely used. there is.

In particular, since the lamp (or lighting) plays an important role in vehicle safety, the vehicle is equipped with a fault diagnosis technology that detects faults such as MCU failure or lamp disconnection or short circuit, and also controls the lamp according to the fault detection results. Technologies are being applied to display fault information or notify the driver.

As shown in Figure 1, a lamp driving system typically includes an MCU (10) that outputs a PWM signal and an enable signal as control signals for lamp control, and a PWM output from the MCU (10) connected to each lamp. It includes an LED driver (e.g. Driver IC) 20 that drives the corresponding lamp according to the signal and enable signal.

At this time, the MCU (10) monitors the operating status of the LED driver (e.g., driver IC) (20) and the lamp (load) and provides a fail-safe function that controls the lamp according to the failure detection result and a failure warning that notifies the driver of the failure. On the other hand, in case of failure of the MCU 10, it is common to turn on the lamp directly by directly driving a switch by the user instead of the MCU control method.

Therefore, in order to improve user convenience, there is a need for a device that automatically detects a malfunction of the MCU 10 and automatically drives the lamp, thereby preventing unintentional lighting off (or lamp off) from occurring.

The background technology of the present invention is disclosed in Korean Patent Publication No. 10-2015-0068669 (published on November 28, 2016, vehicle lamp driving system and method).

According to one aspect of the present invention, the present invention was created to solve the above problems, and detects a failure of the MCU that controls the lamp driver that supplies power to the vehicle lamp and drives the lamp driver. The purpose is to provide a fault compensation device for MCU for vehicle lamps, which prevents unintentional lamp turn-off by the user by applying a signal.

A fault compensation device for MCU for vehicle lamps according to one aspect of the present invention includes a regulator that generates a signal that can be applied as a driving signal to a lamp driver; A pulse detection unit that detects a pulse signal output when an MCU (Micro Control Unit) that applies a driving signal to the lamp driver is in a normal state; And a first unit that receives a signal output from the regulator, switches on and off depending on whether the pulse signal output from the MCU is detected through the pulse detection unit, and outputs or blocks the signal generated by the regulator to the lamp driver. It is characterized in that it includes a switching unit.

In the present invention, the pulse detection unit detects a pulse signal that is periodically output when the MCU is in a normal state. If a pulse signal is output from the MCU, the MCU is in a normal state, and if the pulse signal is not output from the MCU, the pulse detector detects a pulse signal that is periodically output. The MCU is characterized in that it is not in a normal state.

In the present invention, the first switching unit does not output the output of the signal received from the regulator to the lamp driver when a pulse signal is output from the MCU, and when the pulse signal is not output from the MCU, the first switching unit does not output the output of the signal received from the regulator to the lamp driver. It is characterized by being implemented to output a signal received from a regulator to the lamp driver.

In the present invention, when the pulse signal is not output due to a malfunction of the MCU and the first switching unit applies the signal output from the regulator to the lamp driver, a warning light is driven to make the user aware of the malfunction of the MCU. It is characterized by further including ;.

In the present invention, the pulse detection unit includes a first switching element (Q1) that is switched on and off by receiving a pulse signal output from the MCU to a gate terminal through a resistor (R1); and a resistor (R3) and a capacitor (C1) connected in series to output or block the signal generated by the regulator according to the switching on/off of the first switching element (Q1).

In the present invention, if the pulse detection unit does not output a pulse due to a failure of the MCU, the first switching element (Q1) continues to be switched off, and accordingly, the resistor (R3) in the regulator The DC (Direct Current) signal output through the capacitor (C1) is blocked from being output to the first switching unit, and when the MCU outputs a pulse in a normal state, the first switching element (Q1) is switched on. It is characterized in that the pulse-shaped signal output from the regulator through the resistor (R3) while turning off repeatedly passes through the capacitor (C1) and is output to the first switching unit.

In the present invention, the first switching unit is a second switching element that continuously receives a voltage above a certain level applied by the capacitor (C2) to the gate terminal when a pulse-shaped signal is output from the pulse detection unit. (Q2); and as the second switching element (Q2) is switched on, the signal output from the regulator through the resistor (R6) is grounded so that the signal output from the regulator through the resistor (R6) is ramped. It is characterized by being implemented so that it is not applied to the driving unit.

In the present invention, when the pulse signal is not output due to a failure of the MCU, the output signal of the regulator is blocked by the capacitor (C1) of the pulse detection unit, so that the gate terminal of the second switching element (Q2) is continuously low. As the (Low) level signal is applied and the second switching element (Q2) continues to be in the OFF state, the signal output from the regulator through the resistor (R6) is transmitted to the lamp driver through the diode (D3). It is characterized by being implemented to be applied to a designated terminal (PWM in, Enable).

In the present invention, the B+ power detection unit receives battery power through the B+ input terminal and detects whether the voltage level of the battery power is higher than a predetermined voltage level; and receives the signal generated from the regulator, and switches on and off according to whether the voltage level of the battery power is higher than a predetermined voltage level through the B+ power detection unit to transmit the signal generated from the regulator to the first switching unit. It is characterized in that it further includes a second switching unit that outputs or blocks.

In the present invention, the second switching unit outputs a signal received from the regulator to the first switching unit when the voltage level of the battery power detected through the B+ power detection unit is higher than a predetermined voltage level, and the battery If the voltage level of the power supply is lower than a predetermined voltage level, the signal received from the regulator is blocked from being output to the first switching unit.

In the present invention, an IGN+ power detection unit that receives starting power through an IGN+ input terminal and detects vehicle starting based on the voltage level of the starting power; And a third switching unit that receives the signal generated from the regulator, switches on and off depending on whether the vehicle ignition is detected through the IGN+ power detection unit, and outputs or blocks the signal generated by the regulator to the second switching unit. It is characterized in that it further includes a part;

In the present invention, the third switching unit outputs a signal received from the regulator to the second switching unit when vehicle starting is detected by the voltage level of the starting power supply detected through the IGN+ power detection unit, When the vehicle starting is not detected according to the voltage level of the starting power supply, the signal received from the regulator is blocked from being output to the second switching unit.

According to one aspect of the present invention, the present invention detects a failure of the MCU that controls the lamp driver that supplies power to the vehicle lamp and applies a drive signal to the lamp driver, thereby turning off the lamp that is not intended by the user. to prevent it.

Figure 1 is an exemplary diagram schematically showing the configuration of a general lamp driving system.
Figure 2 is an exemplary diagram showing the schematic configuration of a fault compensation device for MC oil for vehicle lamps according to the first embodiment of the present invention.
FIG. 3 is an exemplary diagram showing the circuit configuration of the pulse detection unit 120 and the first switching unit 130 in FIG. 2.
FIG. 4 is a flowchart for explaining the operation of the first switching unit in FIG. 2 according to whether the MCU is broken.
Figure 5 is an exemplary diagram showing the schematic configuration of a fault compensation device for MC oil for vehicle lamps according to a second embodiment of the present invention.
FIG. 6 is a flowchart for explaining the operation of the second switching unit according to the level of the B+ power supply in FIG. 5.
Figure 7 is an exemplary diagram showing the schematic configuration of a fault compensation device for MC oil for vehicle lamps according to a third embodiment of the present invention.
FIG. 8 is a flowchart for explaining the operation of the third switching unit in FIG. 7 according to whether IGN+ power is detected.

Hereinafter, an embodiment of a fault compensation device for MC oil for vehicle lamps according to the present invention will be described with reference to the attached drawings.

In this process, the thickness of lines or sizes of components shown in the drawing may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

Figure 2 is an exemplary diagram showing the schematic configuration of a fault compensation device for MC oil for vehicle lamps according to the first embodiment of the present invention.

As shown in FIG. 2, the MC oil failure compensation device for vehicle lamps according to the first embodiment of the present invention includes a regulator 110, a pulse detection unit 120, and a first switching unit 130. .

The regulator 110 generates and outputs a logical high voltage (e.g., 3.3V) (Q) to apply a logical high voltage to the designated terminal (PWM in, Enable) of the lamp driver 20. .

The regulator 110 may receive power from a battery (not shown) and output the logic high voltage (eg, 3.3V) (Q).

The pulse detection unit 120 detects a pulse signal periodically output when the MCU 10 is in a normal state. For example, if a pulse signal is output from the MCU 10, the MCU 10 can be said to be in a normal state, and if a pulse signal is not output from the MCU 10, the MCU 10 is not in a normal state.

The first switching unit 130 receives a signal (e.g., logic high voltage) output from the regulator 110, and detects a pulse signal output from the MCU 10 through the pulse detection unit 120. Depending on whether the lamp driver 20 is switched on or off, the signal output from the regulator 110 is output to the lamp driver 20 or blocked.

For example, when a pulse signal is output from the MCU 10, the first switching unit 130 blocks the output of the signal (e.g., logic high voltage) received from the regulator 110 (i.e., the regulator ( The signal received from 110) is not output to the lamp driver). On the other hand, when the pulse signal is not output from the MCU 10 (i.e., the MCU is broken), the first switching unit 130 outputs the signal received from the regulator 110 (i.e., the The signal received from the regulator 110 is output to the lamp driver).

As described above, when a failure of the MCU 10 is detected, the first switching unit 130 outputs a signal (e.g., logic high voltage) output from the regulator 110 to the lamp driver 20. The lamp driver 20 operates normally so that the rear lamp (not shown) can be continuously driven.

At this time, although not specifically shown in the drawing, a failure of the MCU 10 is detected, and the signal output from the regulator 110 is automatically applied to the lamp driver 20 through the first switching unit 130. In this case, a warning light (i.e., a warning light indicating a malfunction of the MCU) (not shown) may be driven to make the user aware of the malfunction of the MCU (10).

FIG. 3 is an exemplary diagram showing the circuit configuration of the pulse detection unit 120 and the first switching unit 130 in FIG. 2.

Referring to FIG. 3, the pulse detection unit 120 receives the pulse signal output from the MCU 10 to the gate terminal of the first switching element (Q1) through a resistor (R1) and repeatedly switches on and off. , the signal (i.e., logic high signal) output from the regulator 110 according to the switching on and off of the first switching element (Q1) is output in the form of a pulse through the resistor (R3) and the capacitor (C1). Here, resistance (R3) is the current limiting resistor.

At this time, if the pulse is not output due to a failure of the MCU (10), the first switching element (Q1) continues to be switched off, and accordingly, the regulator (110) outputs the pulse through the resistor (R3). The output of the DC (Direct Current) signal to the next stage (i.e., the first switching unit 130) is blocked through the capacitor C1. On the other hand, when the MCU 10 outputs a pulse in a normal state, the first switching element Q1 repeats switching on and off, and the pulse-shaped signal output from the regulator 110 through the resistor R3 is It passes through the capacitor C1 and is output to the next stage (i.e., the first switching unit 130).

Accordingly, when a pulse-shaped signal is continuously output from the pulse detection unit 120 (i.e., when the MCU 10 outputs a pulse in a normal state), the first switching unit 130 generates a capacitor (C2). ), a voltage above a certain level is continuously applied to the gate terminal of the second switching element (Q2), thereby switching on the second switching element (Q2), thereby reducing the resistance (R6) in the regulator (110). The signal output through the diode D3 (i.e., logic high signal) is grounded, so the signal is not output through the diode D3.

On the other hand, when the pulse signal is not output due to a failure of the MCU 10, the output signal of the regulator 110 is blocked by the capacitor C1, so the gate terminal of the second switching element Q2 is continuously low. A (Low) level signal is applied and the second switching element Q2 continues to be switched off. Accordingly, the DC type signal (i.e., logic high signal) output from the regulator 110 through the resistor R6 is applied to the designated terminal (PWM in, Enable) of the lamp driver 20 through the diode D3. do.

Here, the capacitor (C1) acts as a DC blocking and AC pass filter, the diode (D2) provides only a positive direction voltage to the capacitor (C2), and the diode (D4) acts as a DC blocking and AC passing filter. Prevents voltage drop in the negative direction. Additionally, the resistor R5 determines the voltage level stored in the capacitor C2 by dividing the voltage by the resistor R3. And the second switching element (Q2) performs ON/OFF according to the voltage charged in the capacitor (C2). In addition, the on/off of the logic high signal of the regulator 110 is determined by the second switching element (Q2), the resistor (R6) limits the output current of the regulator 110, and the diode (D3) controls the logic high signal. It serves to output the output in one direction to a designated terminal of the lamp driver 20.

FIG. 4 is a flowchart for explaining the operation of the first switching unit in FIG. 2 according to whether the MCU is broken.

Referring to FIG. 4, when the pulse is normally output from the control unit (i.e., MCU) 10 (example of S101), the first switching unit 130 switches the pulse output from the control unit (i.e., MCU) 10. A signal is input to the corresponding port (i.e., PWM in, Enable) of the lamp driver 20 (S102).

However, if the pulse is not output normally from the control unit (i.e., MCU) 10 (No in S101) (i.e., the MCU is broken), the first switching unit 130 outputs the pulse from the regulator 110. The signal is input to the corresponding port (i.e., PWM in, Enable) of the lamp driver 20 (S103).

Figure 5 is an exemplary diagram showing the schematic configuration of a fault compensation device for MC oil for vehicle lamps according to a second embodiment of the present invention.

As shown in FIG. 5, the fault compensation device for MC oil for vehicle lamps according to the second embodiment of the present invention is the fault compensation device for MC oil for vehicle lamps according to the first embodiment of the present invention shown in FIG. 2. In , it further includes a B+ input terminal 140, a B+ power detection unit 150, and a second switching unit 160.

The B+ power detection unit 150 receives battery power (i.e., B+ power) through the B+ input terminal 140, and detects whether the voltage level of the battery power (i.e., B+ power) is higher than a predetermined voltage level.

The second switching unit 160 receives the signal (e.g., logic high voltage) output from the regulator 110, and receives the voltage of the battery power (i.e., B+ power) through the B+ power detection unit 140. Depending on whether the level is higher than a predetermined voltage level, the signal is switched on/off and the signal output from the regulator 110 is output to the first switching unit 130 or blocked.

For example, when the voltage level of the battery power (i.e., B+ power) detected through the B+ power detection unit 140 is higher than a predetermined voltage level, the second switching unit 160 receives the signal from the regulator 110. is output to the first switching unit 130. However, when the voltage level of the battery power source (i.e., B+ power source) is lower than a predetermined voltage level, the second switching unit 160 blocks the signal received from the regulator 110 (i.e., the regulator 110 The signal received from is not output to the first switching unit 130).

FIG. 6 is a flowchart for explaining the operation of the second switching unit according to the level of the B+ power supply in FIG. 5.

Referring to FIG. 6, when the voltage level of the B+ power source (i.e., battery power) input through the B+ input terminal 140 is higher than a specified voltage level (example of S201), the second switching unit 160 operates the regulator ( The signal output from 110 is output to the first switching unit 130 (S202).

However, if the voltage level of the B+ power input through the B+ input terminal 140 is not higher than the specified voltage level (No in S201), the second switching unit 160 changes the signal output from the regulator 110 to the 1 Blocks output to the switching unit 130 (S203).

Figure 7 is an exemplary diagram showing the schematic configuration of a fault compensation device for MC oil for vehicle lamps according to a third embodiment of the present invention.

As shown in FIG. 7, the fault compensation device for MC oil for vehicle lamps according to the third embodiment of the present invention is the fault compensation device for MC oil for vehicle lamps according to the second embodiment of the present invention shown in FIG. 5. In , it further includes an IGN+ input terminal 170, an IGN+ power detection unit 180, and a third switching unit 190.

The IGN+ power detection unit 180 receives starting power (i.e., IGN+ power) through the IGN+ input terminal 170, and determines whether the voltage level of the starting power (i.e., IGN+ power) is higher than a predetermined voltage level (i.e., Detects whether the vehicle has started.

The third switching unit 190 receives the signal (e.g., logic high voltage) output from the regulator 110, and receives the voltage of the starting power source (i.e., IGN+ power) through the IGN+ power detection unit 180. The signal output from the regulator 110 is switched on/off depending on whether the level is higher than a predetermined voltage level (i.e., the vehicle has been started) to output or block the signal output from the regulator 110 to the second switching unit 160. do.

For example, when the voltage level of the starting power (i.e., IGN+ power) detected through the IGN+ power detection unit 180 is higher than a predetermined voltage level (i.e., when vehicle start is detected), the third switching unit 190 Outputs the signal received from the regulator 110 to the second switching unit 160. However, when the voltage level of the starting power source (i.e., IGN+ power source) is lower than the predetermined voltage level (i.e., when the vehicle starting is not detected), the third switching unit 190 uses the signal received from the regulator 110. blocks (that is, the signal received from the regulator 110 is not output to the second switching unit 160).

FIG. 8 is a flowchart for explaining the operation of the third switching unit in FIG. 7 according to whether IGN+ power is detected.

Referring to FIG. 8, when the voltage level of the IGN+ power input through the IGN+ input terminal 170 is higher than a specified voltage level (i.e., when vehicle start is detected) (example of S201), the third switching unit 190 Outputs the signal output from the regulator 110 to the second switching unit 160 (S302).

However, if the voltage level of the IGN+ power input through the IGN+ input terminal 140 is not higher than the specified voltage level (i.e., when vehicle start is not detected) (No in S201), the third switching unit 190 The signal output from the regulator 110 is blocked from being output to the second switching unit 160 (S303).

As described above, this embodiment detects a failure of the MCU, which controls the lamp driver that supplies power to the vehicle lamp, and applies a drive signal to the lamp driver, thereby preventing the lamp from turning off unintentionally by the user. This has the effect of improving user convenience.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but these are merely illustrative, and various modifications and equivalent embodiments can be made by those skilled in the art. You will understand the point. Therefore, the scope of technical protection of the present invention should be determined by the scope of the patent claims below. Implementations described herein may also be implemented as, for example, a method or process, device, software program, data stream, or signal. Although discussed only in the context of a single form of implementation (eg, only as a method), implementations of the features discussed may also be implemented in other forms (eg, devices or programs). The device may be implemented with appropriate hardware, software, firmware, etc. The method may be implemented in a device such as a processor, which generally refers to a processing device that includes a computer, microprocessor, integrated circuit, or programmable logic device. Processors also include communication devices such as computers, cell phones, portable/personal digital assistants (“PDAs”) and other devices that facilitate communication of information between end-users.

10: MCU 20: Lamp driver
110: regulator 120: pulse detection unit
130: first switching unit 140: B+ input terminal
150: B+ power detection unit 160: second switching unit
170: IGN+ input terminal 180: IGN+ power detection unit
190: third switching unit

Claims (12)

a regulator that generates a signal that can be applied as a driving signal to the lamp driver;
A pulse detection unit that detects a pulse signal output when an MCU (Micro Control Unit) that applies a driving signal to the lamp driver is in a normal state; and
A first switching device that receives a signal output from the regulator, switches on and off depending on whether the pulse signal output from the MCU is detected through the pulse detection unit, and outputs or blocks the signal generated by the regulator to the lamp driver. Part; including,
The pulse detection unit,
A first switching element (Q1) that is switched on and off by receiving the pulse signal output from the MCU to the gate terminal through a resistor (R1); and
A resistor (R3) and a capacitor (C1) connected in series that output or block the signal generated by the regulator according to the switching on and off of the first switching element (Q1). Malfunction of the MC oil for vehicle lamps, comprising a. Compensation device.
The method of claim 1, wherein the pulse detection unit,
When the MCU is in a normal state, it detects a pulse signal that is periodically output,
If a pulse signal is output from the MCU, the MCU is in a normal state, and if a pulse signal is not output from the MCU, the MCU is not in a normal state.
The method of claim 1, wherein the first switching unit,
When a pulse signal is output from the MCU, the output of the signal received from the regulator is not output to the lamp driver,
A fault compensation device for MCU for vehicle lamps, characterized in that it is implemented to output a signal received from the regulator to the lamp driver when the pulse signal is not output from the MCU.
According to clause 1,
When the pulse signal is not output due to a failure of the MCU and the first switching unit applies the signal output from the regulator to the lamp driver,
A fault compensation device for MCU for vehicle lamps, further comprising a warning light driven to notify the user of a malfunction of the MCU.
delete The method of claim 1, wherein the pulse detection unit,
If the pulse is not output due to a failure of the MCU, the first switching element (Q1) continues to be switched off, and accordingly, the DC (Direct Current) signal output from the regulator through the resistor (R3) The output to the first switching unit is blocked through the capacitor C1,
When the MCU outputs a pulse in a normal state, the first switching element (Q1) repeats switching on and off, and the pulse-shaped signal output from the regulator through the resistor (R3) passes through the capacitor (C1). A fault compensation device for MC oil for vehicle lamps, characterized in that the output is output to the first switching unit.
The method of claim 1, wherein the first switching unit,
When a pulse-shaped signal is output from the pulse detection unit, a second switching element (Q2) that continuously receives a voltage above a certain level applied by the capacitor (C2) to the gate terminal,
As the second switching element (Q2) is switched on, the signal output from the regulator through the resistor (R6) is grounded so that the signal output from the regulator through the resistor (R6) is not applied to the lamp driver. Features MCU's fault compensation device for vehicle lamps.
According to clause 7,
When the pulse signal is not output due to a failure of the MCU, the output signal of the regulator is blocked by the capacitor (C1) of the pulse detection unit, thereby continuously generating a low level signal to the gate terminal of the second switching element (Q2). is applied, and as the second switching element (Q2) continues to be switched off, the signal output from the regulator through the resistor (R6) is transmitted to the designated terminal (PWM in) of the lamp driver through the diode (D3). , Enable), a fault compensation device for MCU for vehicle lamps, characterized in that it is implemented to be approved.
According to clause 1,
A B+ power detection unit that receives battery power through the B+ input terminal and detects whether the voltage level of the battery power is higher than a predetermined voltage level; and
The signal generated by the regulator is received, and the signal generated by the regulator is switched on and off according to whether the voltage level of the battery power is higher than a predetermined voltage level through the B+ power detection unit and the signal generated by the regulator is output to the first switching unit. A fault compensation device for MC oil for vehicle lamps, further comprising a second switching unit for switching on or off.
The method of claim 9, wherein the second switching unit,
When the voltage level of the battery power detected through the B+ power detection unit is higher than a predetermined voltage level, a signal received from the regulator is output to the first switching unit,
A fault compensation device for MCU for vehicle lamps, characterized in that when the voltage level of the battery power is lower than a predetermined voltage level, the signal received from the regulator is blocked from being output to the first switching unit.
a regulator that generates a signal that can be applied as a driving signal to the lamp driver;
A pulse detection unit that detects a pulse signal output when an MCU (Micro Control Unit) that applies a driving signal to the lamp driver is in a normal state;
A first switching device that receives a signal output from the regulator, switches on and off depending on whether the pulse signal output from the MCU is detected through the pulse detection unit, and outputs or blocks the signal generated by the regulator to the lamp driver. wealth;
A B+ power detection unit that receives battery power through the B+ input terminal and detects whether the voltage level of the battery power is higher than a predetermined voltage level; and
The signal generated by the regulator is received, and the signal generated by the regulator is switched on and off according to whether the voltage level of the battery power is higher than a predetermined voltage level through the B+ power detection unit and the signal generated by the regulator is output to the first switching unit. Includes a second switching unit for switching or blocking,
IGN+ power detection unit that receives starting power through the IGN+ input terminal and detects vehicle starting based on the voltage level of the starting power; and
A third switching unit that receives the signal generated by the regulator and switches on and off depending on whether the vehicle ignition is detected through the IGN+ power detection unit to output or block the signal generated by the regulator to the second switching unit. A fault compensation device for MCU for vehicle lamps, further comprising:
The method of claim 11, wherein the third switching unit,
When vehicle starting is detected by the voltage level of the starting power detected through the IGN+ power detection unit, outputting a signal received from the regulator to the second switching unit,
A fault compensation device for MC oil for vehicle lamps, characterized in that it blocks the signal received from the regulator from being output to the second switching unit when the vehicle starting is not detected by the voltage level of the starting power supply.

Images