KR20200062720A - Apparatus and method for determining failure of multiple switch sensors - Google Patents

Abstract

The present invention relates to an apparatus for determining a failure of multiple switch sensors, to lower requirements of a micro controller unit (MCU), and a method thereof. According to a preferred embodiment of the present invention, the apparatus comprises: a plurality of diodes connected to a plurality of switch sensors, respectively; a plurality of resistors connected to the plurality of diodes, respectively; a pull-up resistor connected to each of the plurality of resistors; a reference power connected to the pull-up resistor; a first distribution resistor connecting one end to the pull-up resistor and each of the plurality of resistors; a second distribution resistor connected between the other end of the first distribution resistor and the earth; a capacitor filter connecting one end to a node between the other end of the first distribution resistor and the second distribution resistor and connecting the other end to the earth; and a control unit connected to the other end of the first distribution resistor, the second distribution resistor, and the capacitor filter, detecting an integrated voltage of the plurality of switch sensors and using the detected integrated voltage to determine whether each of the plurality of switch sensors is failed.

Description

Apparatus and method for determining failure of multiple switch sensors

The present invention relates to a failure determination apparatus and method, and more particularly to a failure determination apparatus and method of a multi-switch sensor in a vehicle.

Vehicle controllers, such as engine controllers and mission controllers, must operate by finding the optimal driving conditions in accordance with the current state of the vehicle. That is, the vehicle controller operates by receiving inputs of various sensors to determine the state of the vehicle.

Among the above-mentioned various sensors, in the case of a switch sensor, various controllers of a vehicle are driven according to ON or OFF, a clutch switch, an oil pressure switch, a wiper switch, a head lamp switch, a brace switch, and an air conditioner switch , Engine start switch, and the like.

In the case of a recent switch sensor, it is designed to be input to an input pin of a microcontroller unit (MCU) through each interface circuit. In addition, as the number of such switch sensors increases, the requirements of the vehicle controller are also increasing. In particular, due to the increase in the number of input pins of the MCU, the need for a high-spec MCU is required, and the number of interface circuits has increased and becomes complicated. These requirements may not only increase the unit cost but also increase the failure rate.

In addition, the switch sensor has a disadvantage in that it is impossible to diagnose a short circuit of a battery. For example, a phenomenon in which a switch sensor is short-circuited frequently occurs due to various causes such as stamping of a wire harness that is an electric set for supplying electric power to a vehicle controller or damage to various incoming lines. Since the short circuit of the switch sensor causes both nodes of the switch sensor to have a battery voltage, the short circuit of the switch sensor is commonly referred to as a short circuit to battery (SCB).

Accordingly, there is a need to develop a device capable of integrally processing inputs of a plurality of switch sensors and simultaneously diagnosing (fault determination) a battery of the switch sensor.

Republic of Korea Registered Patent No. 10-1887497

Accordingly, the present invention has been devised in view of the above-described circumstances, and a fault determination device of a multi-switch sensor for converting a signal of a multi-switch sensor into one analog signal to monitor the state of the sensor to determine whether the multi-switch sensor has failed The purpose is to provide a method.

A failure determination device of a multi-switch sensor according to a preferred embodiment of the present invention for achieving the above object includes a plurality of diodes connected to each of a plurality of switch sensors; A plurality of resistors connected to each of the plurality of diodes; A pull-up resistor connected to each of the plurality of resistors; A reference power source connected to the pull-up resistor; A first distribution resistor having one end connected to each of the pull-up resistor and the plurality of resistors; A second distribution resistor connected between the other end of the first distribution resistor and ground; A capacitor filter having one end connected to a node between the other end of the first distribution resistor and the second distribution resistor and the other end connected to ground; And the other ends of the first distribution resistor, the second distribution resistor, and the capacitor filter, detecting the integrated voltages of the plurality of switch sensors, and using the detected integrated voltages to detect each of the plurality of switch sensors. Includes a control unit for determining whether the failure.

The plurality of resistors have different resistance values.

The reference power is higher than the battery voltage supplied to the switch sensor when the plurality of switch sensors fail.

The control unit may compare the integrated voltages of the plurality of switch sensors and a previously prepared voltage table and determine whether the plurality of switch sensors have failed using the comparison result.

The controller calculates in advance the integrated voltage according to the ON or OFF of each of the plurality of switch sensors and the integrated voltage according to the battery short circuit of each of the plurality of switch sensors as a table voltage in the voltage table. Can be saved.

The controller may determine the sensor states indicated by the table voltages of the voltage table corresponding to the integrated voltages of the plurality of switch sensors as states of the plurality of switch sensors.

A failure determination method of a multi-switch sensor according to a preferred embodiment of the present invention for achieving the above object is a plurality of diodes connected to each of the plurality of switch sensors, a plurality of resistors connected to each of the plurality of diodes, the plurality of A pull-up resistor connected to each of the resistors, a reference power source connected to the pull-up resistor, a first distribution resistor connected to each of the pull-up resistor and each of the plurality of resistors, and a first connected between the other end of the first distribution resistor and ground 2 In the method of determining a failure of a multi-switch sensor using a failure determination device including a capacitor filter having one distribution resistor and one end connected to a node between the other end of the first distribution resistor and the second distribution resistor and the other end connected to ground. The method comprising: detecting an integrated voltage of the plurality of switch sensors at a node between the first distribution resistor, the second distribution resistor, and the capacitor filter; A comparison step of comparing the integrated voltages of the plurality of switch sensors and a previously prepared voltage table; And a failure determination step of determining whether a plurality of switch sensors have failed using the comparison result.

In the determining of the failure, the sensor states indicated by the table voltages of the voltage table corresponding to the integrated voltages of the plurality of switch sensors may be determined as states of the plurality of switch sensors.

The voltage table may store a pre-calculated integrated voltage according to ON or OFF of each of the plurality of switch sensors, and an integrated voltage according to a battery short circuit of each of the plurality of switch sensors as a table voltage. .

The plurality of resistors have different resistance values.

The reference power is higher than the battery voltage supplied to the switch sensor when the plurality of switch sensors fail.

Therefore, according to the apparatus for determining a failure of a multi-switch sensor according to a preferred embodiment of the present invention, it is possible to determine whether the multi-switch sensor has failed by converting the signal of the multi-switch sensor into one analog signal and monitoring the state of the sensor. .

In addition, basically, MCU requirements are lowered, interface circuits, PCB area, and input pins of MCUs decrease, resulting in a decrease in unit cost.

In addition, as the design becomes more complex, the failure rate due to errors that may occur can be reduced.

1 is a circuit diagram of a fault determination device of a multi-switch sensor according to a preferred embodiment of the present invention.
2 is a view showing the integrated voltage according to the on or off of the multi-switch sensor according to a preferred embodiment of the present invention.
3 is a view showing the integrated voltage of the steady state and the fault state of the multi-switch sensor according to a preferred embodiment of the present invention.
4 is a diagram showing various integrated voltages of a multi-switch sensor according to a normal state and a fault state.
5 is a flowchart of a method for determining a failure of a multi-switch sensor according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, when adding reference numerals to the components of each drawing, it should be noted that the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, although preferred embodiments of the present invention will be described below, the technical spirit of the present invention is not limited to or limited thereto, and can be variously implemented by a person skilled in the art.

1 is a circuit diagram of a fault determination device of a multi-switch sensor according to a preferred embodiment of the present invention.

Referring to FIG. 1, the apparatus 100 for determining a failure of a multi-switch sensor according to a preferred embodiment of the present invention is to collectively diagnose whether a battery is short-circuited by a plurality of switch sensors 200, a plurality of diodes D1, D2, Dn), multiple resistors (R1, R2, Rn), pull-up resistors (R _PULLUP ), reference power supply (V1), first distribution resistor (R _DIV1 ), second distribution resistor (R _DIV2 ), capacitor filter ( C _FILTER ), and a control unit 110.

The plurality of diodes D1, D2, and Dn are connected to each of the plurality of switch sensors 200. Here, the plurality of switch sensors 200, as to drive various devices of the vehicle according to the ON (ON) or OFF (OFF), clutch switch, oil pressure switch, wiper switch, head lamp switch, brace switch, air conditioning switch , An engine start switch, and the like.

The plurality of diodes D1, D2, and Dn are provided according to the number of the plurality of switch sensors 200. For example, when the number of the plurality of switch sensors 200 is N, N of the plurality of diodes D1, D2, and Dn are provided. That is, the plurality of switch sensors 200 may include a first sensor SR1, a second switch sensor SR2, and an Nth switch sensor SRn, and the plurality of diodes may include a first diode D1, a first The second diode D2 and the Nth diode Dn may be included. Hereinafter, for ease of explanation of the invention, N is defined as three.

The plurality of diodes D1, D2, and Dn are PN junction diodes, and the N terminal is connected to each of the plurality of switch sensors 200. When the plurality of diodes D1, D2, and Dn each of the plurality of switch sensors 200 is short-circuited, it can block the effect.

The plurality of resistors R1, R2, and Rn have one end connected to the P terminals of each of the plurality of diodes D1, D2, and Dn. The plurality of resistors R1, R2, and Rn are provided according to the number of the plurality of switch sensors 200. The plurality of resistors may include a first resistor R1, a second resistor R2, and an Nth resistor Rn. It is preferable that the plurality of resistors R1, R2, and Rn have different resistance values. That is, when the plurality of switch sensors 200 operate simultaneously, the plurality of resistors R1, R2, and Rn must have resistance values to prevent the voltages input to the control unit 110 from overlapping in any case. This makes it possible to determine the failure of each of the plurality of switch sensors 200 by the control unit 110.

The pull-up resistor R _PULLUP is connected to the other end of each of the plurality of resistors R1, R2, and Rn.

The reference power supply V1 is connected to the pull-up resistor R _PULLUP . The reference power supply V1 has a voltage that is approximately 1.5 times higher than the battery power of a typical vehicle to enable short circuit diagnosis of each of the plurality of switch sensors 200. The reference power supply V1 is higher than the battery voltage supplied to the switch sensor 200 when the plurality of switch sensors 200 fail. The first distribution resistor R _DIV1 has a plurality of pull-up resistors R _PULLUP Resistors R1, R2, and Rn.

The second distribution resistor R _DIV2 is connected between the other end of the first distribution resistor R _DIV1 and the ground. The resistance values of the first distribution resistor R _DIV1 and the second distribution resistor R _DIV2 are appropriately set, so that the controller 110 can recognize the integrated voltage incorporating the voltages of the plurality of switch sensors 200. Fit within range.

The capacitor filter C _FILTER has one end connected to a node between the other end of the first distribution resistor R _DIV1 and the second distribution resistor R _DIV2 , and the other end connected to ground. The capacitor filter C _FILTER removes unnecessary high frequency components from the voltage input to the controller 110.

The controller 110 is connected to the other end of the first distribution resistor R _DIV1 , the second distribution resistor R _DIV2 , and the capacitor filter C _FILTER . The control unit 110 detects the integrated voltages of the plurality of switch sensors 200. The control unit 110 is a type of microcontroller unit (MCU) having an analog-to-digital converter (ADC) for integrated voltage detection. The control unit 110 determines whether each of the plurality of switch sensors 200 has failed using the detected integrated voltage.

The control unit 110 receives different voltages according to a plurality of resistors R1, R2, and Rn connected to the plurality of switch sensors 200, and integrates the received voltages and monitors the voltage state of the integrated voltages. It is determined whether the failure of the switch sensor 200.

The control unit 110 may provide in advance an integrated voltage generated according to the number of failures of the plurality of switch sensors 200 (eg, a short circuit of the battery), on, and off, as a voltage table. Can be. The controller 110 compares the integrated voltage input to the ADC pin and the table voltage of the voltage table provided in advance to determine the current state of the plurality of switch sensors 200.

The controller 110 may determine the sensor states indicated by the table voltages of the voltage table corresponding to the integrated voltages of the plurality of switch sensors 200 as states of the plurality of switch sensors 200.

Hereinafter, a voltage table used for state determination of the plurality of switch sensors 200 will be described.

2 is a view showing an integrated voltage according to ON (ON) or off (OFF) of a multi-switch sensor according to a preferred embodiment of the present invention.

Referring to FIG. 2, the plurality of switch sensors 200 include a first switch sensor SR1, a second switch sensor SR2, and a third switch sensor SR3. The integrated voltages of the plurality of switch sensors 200 appear differently according to ON or OFF of each of the first switch sensor SR1, the second switch sensor SR2, and the third switch sensor SR3. The integrated voltages of the plurality of switch sensors 200 may be calculated in advance and stored in the voltage table.

For example, when the first switch sensor SR1, the second switch sensor SR2, and the third switch sensor SR3 are all OFF, the integrated voltage of the plurality of switch sensors 200 is approximately 4.4V. Appears as

In addition, when the first switch sensor SR1 is ON and the second switch sensor SR2 and the third switch sensor SR3 are OFF, the integrated voltage of the plurality of switch sensors 200 is Approx. 3.7V.

In addition, when the second switch sensor SR2 is ON and the first switch sensor SR1 and the third switch sensor SR3 are OFF, the integrated voltage of the plurality of switch sensors 200 is Approximately 3.1V.

In addition, when the third switch sensor SR3 is ON and the first switch sensor SR1 and the second switch sensor SR2 are OFF, the integrated voltage of the plurality of switch sensors 200 is Approximately 2.7V.

In addition, when the first switch sensor SR1 and the second switch sensor SR2 are ON and the third switch sensor SR3 is OFF, the integrated voltages of the plurality of switch sensors 200 are Approx. 2.75V.

In addition, when the first switch sensor SR1, the second switch sensor SR2, and the third switch sensor SR3 are ON, the integrated voltages of the plurality of switch sensors 200 appear to be approximately 2.0V. .

In addition, when the first switch sensor SR1 is OFF and the second switch sensor SR2 and the third switch sensor SR3 are ON, the integrated voltages of the plurality of switch sensors 200 are Approx. 2.18V.

In addition, when the first switch sensor SR1 and the third switch sensor SR3 are ON and the second switch sensor SR2 is OFF, the integrated voltages of the plurality of switch sensors 200 are Approximately 2.41V.

The integrated voltages of the plurality of switch sensors 200 described above are stored in a voltage table so that each of the first switch sensor SR1, the second switch sensor SR2, and the third switch sensor SR3 is turned on or off. It is used as a basis for judging whether it is (OFF).

3 is a view showing the integrated voltage of the steady state and the fault state of the multi-switch sensor according to a preferred embodiment of the present invention.

Referring to FIG. 3, the integrated voltage according to ON or OFF of the plurality of switch sensors 200 in the normal state as described in FIG. 2 and the first switch sensor SR1 are in a fault state In the case of (battery short circuit), it is possible to check the integrated voltage according to ON or OFF of the plurality of switch sensors 200. Hereinafter, since the integrated voltages of the plurality of switch sensors 200 in the normal state are as shown in FIG. 2, descriptions thereof will be omitted.

When the first switch sensor SR1 is in a fault condition (battery short circuit), the integrated voltages of the plurality of switch sensors 200 exclude the first switch sensor SR1, and the second switch sensor SR2, third It appears differently according to each ON or OFF of the switch sensor SR3. The integrated voltages of the plurality of switch sensors 200 may be calculated in advance and stored in the voltage table.

For example, when both the second switch sensor SR2 and the third switch sensor SR3 are in an OFF state, the integrated voltage of the plurality of switch sensors 200 is the voltage when the first switch sensor SR1 is normal. (Approximately 4.4V).

In addition, when the second switch sensor SR2 is ON and the third switch sensor SR3 is OFF, the integrated voltage of the plurality of switch sensors 200 is the first switch sensor SR1. It appears slightly higher than the normal voltage (approximately 3.1V).

In addition, when the third switch sensor SR3 is ON and the second switch sensor SR2 is OFF, the integrated voltage of the plurality of switch sensors 200 is the first switch sensor SR1. It appears slightly higher than the normal voltage (approximately 2.7V).

The integrated voltages of the plurality of switch sensors 200 are stored in a voltage table and used as a basis for determining whether the first switch sensor SR1 is in a fault condition (battery short circuit).

In addition, the integrated voltages of the plurality of switch sensors 200 when the second switch sensor SR2 is broken and when the third switch sensor SR3 is broken are also stored in the voltage table, so that the second switch sensor SR2 is And it is apparent that the third switch sensor SR3 is used as a basis for determining whether a fault condition exists. This can be confirmed in FIG. 4.

4 is a diagram showing various integrated voltages of a multi-switch sensor according to a normal state and a fault state.

Referring to FIG. 4, the integrated voltage according to ON or OFF of the plurality of switch sensors 200 in the normal state, and the plurality of switch sensors in the case where the first switch sensor SR1 is in a fault state Integrated voltage according to ON or OFF of 200, according to ON or OFF of the plurality of switch sensors 200 when the second switch sensor SR2 is in a fault condition The integrated voltage and the integrated voltage according to the ON (off) of the plurality of switch sensors 200 when the third switch sensor SR3 is in a fault state may be checked.

The above-mentioned various integrated voltages are calculated in advance and stored in the voltage table, and are used to determine the normal state, the fault state, and the ON or OFF state of the plurality of switch sensors 200.

On the other hand, the status determination of the plurality of switch sensors 200 may be made through a comparison of the preset reference voltage levels LV1 to LV9 and the integrated voltages of the plurality of switch sensors 200, and may be represented as shown in Table 1 below. have.

1st switch sensor (SR1) Second switch sensor (SR2) 3rd switch sensor (SR3) LV1 or higher OFF, steady state OFF, steady state OFF, steady state Between LV1 and LV2 Unknown, short circuit (SCB) condition OFF, steady state OFF, steady state Between LV2 and LV3 OFF, steady state Unknown, short circuit (SCB) condition OFF, steady state Between LV3 and LV4 OFF, steady state OFF, steady state Unknown, short circuit (SCB) condition Between LV4 and LV5 ON, steady state Unknown, unknown Unknown, unknown Between LV5 and LV6 Unknown, unknown ON, steady state Unknown, unknown Between LV6 and LV7 Unknown, unknown Unknown, unknown Unknown, unknown Between LV7 and LV8 ON, steady state Unknown, unknown ON, steady state Between LV8 and LV9 Unknown, unknown ON, steady state ON, steady state Less than LV9 ON, steady state ON, steady state ON, steady state

In Table 1, LV1 to LV9 indicate the reference voltage level, ON indicates the ON state of the switch sensor, OFF indicates the OFF state of the switch sensor, and the normal state indicates that the switch sensor is normal, The battery short circuit (SCB) state indicates that the switch sensor is defective (battery short circuit), and in the case of'unknown', it indicates that the plurality of switch sensors is in an unknown state.

Among the reference voltage levels, the first voltage level LV1 may be set to approximately 4.5V, and the ninth voltage level LV9 may be set to approximately 2.0V. Also, the second voltage level LV2 to the eighth voltage level LV8 may be appropriately set. In addition, the reference voltage levels LV1 to LV9 may be further subdivided to increase the number thereof, which enables accurate state determination of the plurality of switch sensors 200. That is, in Table 1, in the case of'unknown', the sub-segments of the reference voltage levels LV1 to LV9 may be changed to a normal state, a fault state, or an on or off state of a plurality of switch sensors.

5 is a flowchart of a method for determining a failure of a multi-switch sensor according to a preferred embodiment of the present invention.

1 and 5, a method for determining a failure of a multi-switch sensor according to a preferred embodiment of the present invention includes a detection step (S510 ), a comparison step (S520 ), and a failure determination step 530.

First, in the detection step (S510), the control unit 110 of the plurality of switch sensors 200 at the node between the first distribution resistance (R _DIV1 ), the second distribution resistance (R _DIV2 ), and the capacitor filter (C _FILTER ) Integrated voltage is detected.

Then, in the comparison step (S520), the control unit 110 compares the integrated voltages of the plurality of switch sensors 200 and a previously prepared voltage table.

Then, in the failure determination step (S530), the control unit 110 determines whether or not the plurality of switch sensors 200 fail using the comparison result. At this time, the controller 110 may determine the sensor states indicated by the table voltages of the voltage table corresponding to the integrated voltages of the plurality of switch sensors 200 as states of the plurality of switch sensors 200. Meanwhile, the control unit 110 may set a plurality of reference voltage levels to determine the states of the plurality of switch sensors 200 according to which reference voltage level the integrated voltage of the plurality of switch sensors 200 corresponds to.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit of the present invention, but to explain the scope of the technical spirit of the present invention. .

The steps and/or operations according to the present invention may occur simultaneously in other embodiments, in different order, or in parallel, or in different embodiments for different epochs, etc., as can be understood by one skilled in the art. You can.

Depending on the embodiment, some or all of the steps and/or actions drive instructions, programs, interactive data structures, clients and/or servers stored in one or more non-transitory computer-readable media. At least some may be implemented or performed using one or more processors. The one or more non-transitory computer-readable media may illustratively be software, firmware, hardware, and/or any combination thereof. In addition, the functionality of the “module” discussed herein may be implemented in software, firmware, hardware, and/or any combination thereof.

100: failure determination device
110: control unit
D1, D2, Dn: first, second, and N diodes
R1, R2, Rn: 1st, 2nd, Nth resistance
R _PULLUP : Pull-up resistance
V1: Reference power
R _DIV1 , R _DIV2 : 1st, 2nd distribution resistance
C _FILTER : Capacitor filter
200: multiple switch sensors
SR1, SR2, SR3: 1st, 2nd, 3rd switch sensor

Claims (11)

A plurality of diodes connected to each of the plurality of switch sensors;
A plurality of resistors connected to each of the plurality of diodes;
A pull-up resistor connected to each of the plurality of resistors;
A reference power source connected to the pull-up resistor;
A first distribution resistor having one end connected to each of the pull-up resistor and the plurality of resistors;
A second distribution resistor connected between the other end of the first distribution resistor and ground;
A capacitor filter having one end connected to a node between the other end of the first distribution resistor and the second distribution resistor and the other end connected to ground; And
Connected to the other end of the first distribution resistor, the second distribution resistor, and the capacitor filter, detects the integrated voltages of the plurality of switch sensors, and uses the detected integrated voltage to detect the failure of each of the plurality of switch sensors. A control unit for determining whether or not;
Fault determination device of a multi-switch sensor comprising a. According to claim 1,
The plurality of resistors have different resistance values, characterized in that the failure determination device of a multi-switch sensor. According to claim 1,
The reference power supply is a fault determination device of a multi-switch sensor, characterized in that when the failure of the plurality of switch sensors is higher than the battery voltage supplied to the switch sensor. According to claim 1,
The control unit,
A fault determination device for a multi-switch sensor, characterized by comparing the integrated voltages of the plurality of switch sensors and a pre-prepared voltage table and determining whether the plurality of switch sensors have failed using the comparison result. The method of claim 4,
The control unit,
It is characterized in that the integrated voltage according to the ON or OFF of each of the plurality of switch sensors and the integrated voltage according to the battery short circuit of each of the plurality of switch sensors are calculated in advance and stored as a table voltage in the voltage table. Fault determination device for multiple switch sensors. The method of claim 5,
The control unit,
A fault determination device for a multi-switch sensor, characterized in that the sensor states indicated by the table voltages of the voltage table corresponding to the integrated voltages of the plurality of switch sensors are determined as states of the plurality of switch sensors. A plurality of diodes connected to each of the plurality of switch sensors, a plurality of resistors connected to each of the plurality of diodes, a pull-up resistor connected to each of the plurality of resistors, a reference power source connected to the pull-up resistor, one end of which is connected to the pull-up resistor A node between a first distribution resistor connected to each of the plurality of resistors, a second distribution resistor connected between the other end of the first distribution resistor and ground, and one end between the other end of the first distribution resistor and the second distribution resistor In the failure detection method of a multi-switch sensor using a failure determination device including a capacitor filter connected to the other end is connected to the ground,
A detection step of detecting an integrated voltage of the plurality of switch sensors at a node between the first distribution resistance, the second distribution resistance, and the capacitor filter;
A comparison step of comparing the integrated voltages of the plurality of switch sensors and a previously prepared voltage table; And
A failure determination step of determining whether a plurality of switch sensors have failed using the comparison result;
Fault determination method of a multi-switch sensor comprising a. The method of claim 7,
The failure determination step,
A method for determining a failure of a multi-switch sensor, characterized in that the sensor states indicated by the table voltages of the voltage table corresponding to the integrated voltages of the plurality of switch sensors are determined as states of the plurality of switch sensors. The method of claim 7,
The voltage table,
Multiple switches, characterized in that the pre-calculated integrated voltage according to each of the plurality of switch sensors on (ON) or off (OFF) and the integrated voltage according to the battery short circuit of each of the plurality of switch sensors as a table voltage How to judge the failure of the sensor. The method of claim 7,
The plurality of resistors have different resistance values, characterized in that the failure determination method of a multi-switch sensor. The method of claim 7,
The reference power supply is a fault determination method of a multi-switch sensor, characterized in that higher than the battery voltage supplied to the switch sensor when the plurality of switch sensors fail.

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