KR100920903B1 - Power Fail Safe Circuit of Smart Key System - Google Patents

Abstract

The present invention relates to a power stage fail-safe circuit in a smart key system, and more particularly, when a main microcomputer of a power distribution module (PDM) is damaged, by using an auxiliary microcomputer and an RS latch, the vehicle is safely operated without additional diagnostic logic. A fail safe circuit for preserving the starting state.

The power stage fail safe circuit in the smart key system according to the present invention comprises a start button and a PDM and a relay box;

The PDM performs power state movement by checking a start button press time, and drives a relay box for power movement by performing time control by inputting a start button in a state in which a power state of a vehicle is stored in a memory. A microcomputer, an auxiliary microcomputer that performs the role of the main microcomputer when the main microcomputer is inoperable, and determines a power state and an inoperable state of the main microcomputer and the auxiliary microcom, and powers the relay box by an RS latch. Characterized in that the power stage comparator to determine the supply.

Smart Key System, PDM, Secondary Microcom, RS Latch

Description

Power Fail Safe Circuit of Smart Key System

The present invention relates to a power stage fail-safe circuit in a smart key system, and more particularly, when a main microcomputer of a power distribution module (PDM) is damaged, by using an auxiliary microcomputer and an RS latch, the vehicle is safely operated without additional diagnostic logic. A fail safe circuit for preserving the starting state.

In general, the smart key allows the driver to open and close the door and start the vehicle from the outside without a separate key insertion or operation button operation, and a smart card and a fob are easy to carry.

1 is a view for explaining the problem of the prior art in the smart key system.

In FIG. 1, the smart ECU 1 communicates with the smart key to determine whether the user is a legitimate user, and provides the engine ECU 2 with permission to start the engine according to the determination result.

However, in the conventional control method, when the control line from the smart ECU 1 to the relay 3 going to the engine ECU 2 is broken or the output micom of the power distribution module is broken or the smart ECU 1 is started, the vehicle is started while driving. The condition may turn off and a dangerous situation may occur, or the engine may cry or stall.

As described above, the protection device is protected by various protection elements for fail safe of the microcomputer application unit, but there is no countermeasure when the microcomputer of the unit is inoperable, and the countermeasure when the microcomputer is inoperable while driving is required.

The present invention has been made to solve the above-described problems, when the main microcomputer of the power distribution module (PDM) is damaged by using the auxiliary microcomputer and the RS latch can be safely maintained during the running state of the vehicle without additional diagnostic logic The purpose is to provide a power fail fail safe circuit in a smart key system.

Power stage fail-safe circuit in the smart key system according to the present invention for achieving the above object, comprises a start button and a PDM and a relay box;

The PDM performs power state movement by checking a start button press time, and drives a relay box for power movement by performing time control by inputting a start button in a state in which a power state of a vehicle is stored in a memory. A microcomputer, an auxiliary microcomputer that performs the role of the main microcomputer when the main microcomputer is inoperable, and determines a power state and an inoperable state of the main microcomputer and the auxiliary microcom, and powers the relay box by an RS latch. Characterized in that the power stage comparator to determine the supply.

According to the above-described problem solving means, it is possible to safely maintain the starting state while the vehicle is running without any additional diagnostic logic.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

2 is an overall block diagram of a power supply fail safe system according to the present invention.

As shown, the smart key system includes a start button 100, a power distribution module (PDM) 200, a relay box 300, and an engine ECU 400.

The PDM 200 performs power state movement by checking the start time of the start button 100, and performs time control by input of the start button 100 in a state in which the power state of the vehicle is stored in a memory. When driving the relay box 300 for movement, and the engine ECU 400 is released and can be started, the power is supplied to the START relay 308 of the relay box 300.

The PDM 200 includes a main microcomputer 210, an auxiliary microcomputer 220, and a power stage comparator 230.

The main microcomputer 210 plays the role of the PDM 200, and when the main microcomputer 210 is inoperable, the secondary microcomputer 220 plays the role of the PDM 220 in place of the main microcomputer 210. The power stage comparator 230 determines the power state and the inoperable state of the primary microcomputer 210 and the secondary microcomputer 220 to determine the power supply to the relay box 300 by the RS latch.

The latch circuit is a circuit in which the logic state of the output signal is unchanged even when a transition of the logic state of some input signals occurs, including the RS latch circuit.

3 is a detailed block diagram of the power stage comparator shown in FIG. 2.

As shown, the power state determination unit 231, the first operation determination unit 232, the second operation determination unit 233, the power state and operation determination unit 234, and the RS latch unit 235 It is configured to include.

The power state determination unit 231 determines the IGN1 power state of the microcomputer (main microcomputer + secondary microcomputer) by AND logic using the IGN1 signals of the primary microcomputer 210 and the secondary microcomputer 220 as input signals.

When the IGN1 ON of the primary microcomputer 210 and the auxiliary microcomputer 220 is input to 1 in the power state determination unit 231 and 0 is input in the OFF state, the power state determination unit 231 is connected to the main microcom 210. Only when all of the IGN1 ON signals of the auxiliary microcomputer 220 input 1, the IGN1 power state is determined to be normal, and 1 is output. Otherwise, O is output.

The first inoperability determination unit 232 determines whether the microcomputer is inoperable by OR logic using the inoperable signals of the primary microcomputer 210 and the auxiliary microcomputer 220 as input signals.

When the primary microcomputer 210 and the auxiliary microcomputer 220 input the inoperable signal to the first inoperation determination unit 232 as 0, respectively, and input the inoperable signal as 1 in abnormal operation, the first If there is any signal input as 1, the operation determining unit 232 determines that the microcomputer is inoperable and outputs 1 as the microcomputer inoperable signal. Otherwise, it is determined that the microcomputer is in normal operation and is 0 as the microcomputer inoperable signal. Outputs

The output signal of the first malfunction determining unit 232 of the second malfunction determining unit 233 and the output signal of the start button 100 are input signals. To judge.

Pressing the start button in the start button 100, 1 if there is an output signal, 0 if there is no output signal, the first non-operation determination unit 232 is 1 if the microcomputer operation is disabled, 0 if the microcomputer operation is normal, the second operation When inputting to the disable determination unit 233, the second inoperation determination unit 233 is only when both the signal input from the start button 100 and the signal input from the first malfunction determination unit 232 are 1. It is determined that the microcomputer is inoperable according to the button input signal and outputs 1 as the microcomputer inoperable signal. Otherwise, the microcomputer is determined to be normal in accordance with the button input signal.

The power state and inoperability determination unit 234 uses the IGN1 abnormal power state output signal of the power state determination unit 231 and the output signal of the second inoperability determination unit 233 as input signals to perform microcontrollers in OR logic. It determines whether the microcomputer is inoperable according to the IGN1 power state and button input signal.

When an abnormal state 0 is input as the IGN1 power state signal of the power state determination unit 231, and 0 or 1 is input as the output signal of the second inoperability determination unit 233, the power state and the inoperation determination are determined. The unit 234 outputs 1 when any signal inputted to 1 is output, and 0 otherwise.

As shown in Table 1 below, the RS latch unit 235 receives the IGN1 normal power state output signal of the power state determination unit 231 as an input signal S, and the power state and inoperability determination unit 234. When an input signal is received using the output signal R) as the input signal R, the signal Q is output according to the combination of those input signals R and S.

4A and 4B are internal operation diagrams of the power stage comparator shown in FIG. 3 in the normal operation and the abnormal operation of the main microcomputer.

As shown in FIG. 4A, when the main microcomputer 210 and the secondary microcomputer 220 operate normally, all zeros are set as an inoperable signal of the main microcomputer 210 and the auxiliary microcomputer 220. The first inoperability determination unit 232 inputs 0 to the second inoperation determination unit 233 as a microcomputer inoperation signal because it is less than one.

The second inoperation determination unit 233 inputs 0 to the power supply state and inoperation determination unit 234 as a result of the signal 1 input by pressing the microcomputer inoperation signal 0 and the start button 100.

On the other hand, the power state determination unit 231 inputs 1 of ON as the signal S of the RS latch unit 235 when the IGN1 of the primary microcomputer 210 and the secondary microcomputer 220 are both turned on and 1 is input. If any one of IGN1 of the primary microcomputer 210 and the secondary microcomputer 220 is turned off and 0 is input, the zero of the OFF is input to the power supply state and the inoperation determination unit 234 due to abnormal operation.

The power state and inoperability determination unit 234 inputs 0 as a signal R of the RS latch unit 235 as a result of 0 in the second inoperation determination unit 233 and 0 in the power state determination unit 231.

Since the RS latch unit 235 has a signal R of 0 and a signal S of 1, the RS latch unit 235 outputs 1 based on the result of Table 1 to supply power to the IGN1 relay 302 of the relay box 300.

Next, as shown in FIG. 4B, when the main microcomputer 210 operates abnormally and the auxiliary microcomputer 220 operates normally, 1 is an inoperable signal of the main microcomputer 210, and 0 is an inoperable signal of the auxiliary microcomputer 220. The first malfunction determining unit 232 is input to the first malfunction determining unit 232, so that the first malfunction determining unit 232 inputs 0 to the second malfunction determining unit 233 as a microcomputer inoperable signal.

The second inoperation determination unit 233 inputs 1 to the power state and inoperation determination unit 234 as a result of the signal 1 input by pressing the microcomputer inoperation signal 1 and the start button 100.

On the other hand, the power state determination unit 231 inputs 1 of ON as the signal S of the RS latch unit 235 when the IGN1 of the primary microcomputer 210 and the secondary microcomputer 220 are both turned on and 1 is input. If any one of IGN1 of the primary microcomputer 210 and the secondary microcomputer 220 is turned off and 0 is input, the zero of the OFF is input to the power supply state and the inoperation determination unit 234 due to abnormal operation.

The power state and inoperability determination unit 234 inputs 1 as a signal R of the RS latch unit 235 as a result of 1 in the second inoperability determination unit 233 and 0 in the power state determination unit 231.

Since the RS latch unit 235 has a signal R of 1 and a signal S of 1, the RS latch unit 235 maintains the previous state based on the result of Table 1, and thus, FIG. 4A transfers when the main microcomputer 210 of FIG. Since the state is maintained at 1, the IGN1 power is continuously supplied to the IGN1 relay 302 of the relay box 300.

As such, even when the main microcomputer 210 does not operate normally, the IGN1 power may be supplied to the relay box 300 by linking the auxiliary microcomputer 220 and the power stage comparator 230.

Although the configuration and operation of the IGN1 power supply have been described above, the configuration and operation of the IGN2 power supply are the same.

1 is a view for explaining the problems of the prior art in the smart key system,

2 is an overall block diagram of a power supply fail safe system according to the present invention;

3 is a detailed block diagram of the power stage comparator shown in FIG. 2;

4A and 4B are internal operation diagrams of the power stage comparator shown in FIG. 3 during normal operation and abnormal operation of the main microcomputer.

<Description of the symbols for the main parts of the drawings>

100: start button 200: power distribution module (PDM)

210: master microcomputer 220: secondary microcomputer

230: power stage comparator 231: power state determination unit

232,233: Inoperability determination unit 234: Power state and inoperability determination unit

235: RS latch portion 300: relay

400: engine ECU

Claims (4)

Including a start button, a power distribution module (PDM) and a relay box; The PDM performs power state movement by checking a start button press time, and drives a relay box for power movement by performing time control by inputting a start button in a state in which a power state of a vehicle is stored in a memory. Microcomputer, An auxiliary microcomputer that performs the role of the main microcomputer in the event of inoperability of the main microcomputer; The power stage fail safe circuit of the smart key system, characterized in that the power stage comparator for determining the power supply state and the inoperable state of the primary and secondary microcomputer to determine the power supply to the relay box by the RS latch. The method of claim 1, The power stage comparator includes a power state determination unit configured to determine and output a power state of the microcomputer (main microcomputer + secondary microcomputer) by AND logic using the power signals of the primary microcomputer and the secondary microcomputer as input signals; A first inoperation determining unit configured to determine whether the microcomputer is inoperable by OR logic using the inoperable signals of the main microcomputer and the auxiliary microcom as an input signal; A second malfunction determining unit configured to determine whether the microcomputer is inoperable according to the button input signal by AND logic using the output signal of the first malfunction determining unit and the output signal of the start button as an input signal; Power supply for judging whether or not the microcomputer is inoperable according to the microcomputer power state and the button input signal by OR logic using the abnormal power state output signal of the power state determination unit and the output signal of the second inoperability determination unit as input signals. State and inoperability determination unit, In the normal power state of the power state determination unit, a signal 1 is input when the main microcomputer IGN1 is 0n, a signal 0 when the main microcomputer IGN1 is off, and a signal 0 when the auxiliary microcomputer IGN1 is off. Receives 0,1,0,1 signals of four conditions output from the power supply state and the inoperability determining unit as an input signal R and outputs a signal according to a combination of the input signal S and the input signal R, wherein the input signal When R and input signal S are respectively 0, no signal is output. When input signal R is 0 and input signal S is 1, signal 1 is output. When input signal R is 1 and input signal S is 0, When the input signal R is 1 and the input signal is 1 day, the signal is output to the relay box to maintain the output of the state 1 before the IGN1 power is supplied to the IGN1 relay of the relay box. RS latch part; Power stage fail safe circuit in the smart key system, characterized in that consisting of. delete The method of claim 2, The power supply fail safe circuit of the smart key system, characterized in that the power supply of the primary and secondary microcomputer IGN1 or IGN2.

Images