KR20150054514A - Apparatus and method for generating ecu wake up signals sensing pulse duty - Google Patents

Abstract

An apparatus and a method for generating ECU wake up signals sensing pulse duty are provided to sense the difference of pulse duty between a door signal created when a door is unlocked and a door signal created when the door is locked, to create a pulse signal when the door is unlocked, to retrigger and output, and to accurately distinguish the door signals when the door is locked and when the door is unlocked even if it takes a long time for wake up of ECU. The apparatus of the present invention comprises: a first transistor that is turned on/off responding to a door signal and pulls up a first node; a first capacitor that, when the first transistor is turned off, supplies an electric charge to the first node; a calculation amplifier that compares the potential of the first node and a standard voltage and creates a pulse signal; and a standard voltage creating unit that provides the standard voltage to the calculation amplifier.

Description

FIELD OF THE INVENTION [0001] The present invention relates to an apparatus and method for generating a wake-

The present invention relates to an apparatus and method for generating an electronic control unit wake-up signal for detecting a pulse duty, and more particularly, to an apparatus and method for generating an electronic control unit wake-up signal for detecting a pulse duty by detecting a difference in pulse duty between a door signal generated when a door is unlocked and a door signal generated when the door is locked And outputting a pulse signal when the door is unlocked, and to an electronic control unit wake-up signal generating apparatus and method for sensing a pulse duty.

Generally, a suspension installed in an automobile absorbs impact transmitted from a road surface to improve ride quality, and also improves the tractive force of a tire when there is unevenness on the road surface, thereby securing a driving force and a braking force.

Such a suspension is made up of a shock absorber and a spring, and in recent years, an air suspension using an air spring has been widely used. Particularly, an electronic control suspension (electronic control suspension) for controlling the degree of air flow in and out of an air spring is widely used.

The electronic control suspension controls the damping of the spring by controlling the degree of air inflow and outflow to the suspension in real time according to the road surface condition and the driving situation during the driving of the vehicle. The control of the damping is controlled by an electronic control unit I will be in charge.

That is, the electronic control unit receives a signal indicating the road surface condition and running condition from the suspension of the vehicle, and controls the damping of the spring of the suspension. The electronic control unit operates by using the battery of the vehicle as a power source. However, when the operation of the electronic control unit, such as the start-up of the vehicle, is unnecessary, power supply to the electronic control unit increases the consumption of unnecessary batteries.

Therefore, in order to reduce the current consumption of the automobile battery, when the operation of the electronic control unit such as the ignition is not necessary, the electronic control unit enters the sleep mode and the power supply to the electronic control unit is interrupted in the sleep mode .

However, when a signal indicating that the operation of the electronic control unit is required is input from each part of the vehicle, the electronic control unit wakes up and starts normal operation.

Such a wake-up signal can be generated and braked to the electronic control unit when the vehicle is started, when the trunk of the vehicle is opened and closed, and when the door of the vehicle is locked or unlocked.

Related Prior Art Korean Patent Publication No. 1999-006140 (published on Nov. 25, 1999, entitled " Inventive Communication System for Cluster Control ") is available.

The present invention detects a difference between pulse durations of a door signal generated when a door is unlocked and a door signal generated when a door is locked to generate a pulse signal when the door is unlocked and retrigger the pulse signal to output a wake- And it is an object of the present invention to provide an electronic control unit wake-up signal generating apparatus and method for detecting a pulse duty which can accurately discriminate a door signal when a door is locked and an unlocked door when an unlocked door is long.

According to an aspect of the present invention, there is provided an electronic control unit wake-up signal generating apparatus for detecting a pulse duty, the apparatus comprising: a first transistor that is turned on and off in response to a door signal to pull up a first node; An operational amplifier for comparing a potential of the first node with a reference voltage to generate a pulse signal, and a reference voltage generator for providing the reference voltage to the operational amplifier .

The present invention is characterized by further comprising pulse retry rejection for retriggering the pulse signal to output a signal delayed in pulse width.

In the present invention, the first transistor is turned on to pull up the first node when the door signal is at a low level.

In the present invention, the first capacitor is connected between the first node and ground.

In the present invention, the reference voltage generator is a voltage distributor connected between a power source and a ground.

In the present invention, the reference voltage is lower than the potential drop threshold of the first node while the first node is not pulled up when the door of the vehicle is locked, and is lower than the potential drop threshold of the first node when the door is unlocked. Is higher than the limit of the potential drop of one node.

In the present invention, the operational amplifier generates a pulse signal when the potential of the first node is lower than the reference voltage.

According to another aspect of the present invention, there is provided an electronic controller wake-up signal generating method for detecting a pulse duty, the method comprising: a first transistor pulling up a potential of a first node in response to a door signal; Comparing the reference voltage, and generating an operational amplifier pulse signal when the potential of the first node is lower than the reference voltage.

In an electronic control unit wake-up signal generation method for detecting a pulse duty according to the present invention, in the step of generating the pulse signal, a pulse retry is performed by retriggering a pulse signal generated by the operational amplifier to delay a pulse width And outputs the output signal.

In the step of pulling up the first node, the first transistor is turned on to turn on the first node when the door signal is at a low level, Up operation.

The reference voltage is lower than the potential drop limit of the first node while the first node is not pulled up when the door of the vehicle is locked, Is higher than the limit of the potential drop of the first node while the first node is not pulled up.

In the method of generating an electronic control unit wake-up signal for detecting a pulse duty according to the present invention, the operational amplifier outputs a low level signal when the potential of the first node is not lower than the reference voltage.

According to the present invention, a door signal generated when a door is unlocked and a door signal generated when a door is locked are detected, and when a door is unlocked, a pulse signal is generated and retriggered to output a wake- It is possible to accurately distinguish the door signal when the door is locked and the door signal when the door is unlocked.

1 is a circuit diagram of an electronic control unit wake-up signal generating apparatus for detecting pulse duty according to an embodiment of the present invention.
2 is a diagram illustrating potentials of a first node, a door signal, and an output of an operational amplifier according to an embodiment of the present invention.
3 is a flowchart illustrating an operation of an electronic control unit wake-up signal generating method for detecting pulse duty according to an embodiment of the present invention.

Hereinafter, an apparatus and method for generating an electronic control unit wake-up signal for detecting pulse duty according to the present invention will be described in detail with reference to the accompanying drawings.

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

1 is a block diagram of an electronic control unit wake-up signal generating apparatus for detecting pulse duty according to an embodiment of the present invention.

1, an apparatus for generating an electronic control unit wake-up signal for detecting pulse duty according to an embodiment of the present invention includes a first transistor 100, a first capacitor 200, a reference voltage generator 300, An operational amplifier 400, and a pulse rejection filter 500.

As described above, when the starting of the vehicle is turned off, the electronic control unit (not shown) of the vehicle enters the sleep mode and the power supply to the electronic control unit is cut off.

When the door of the vehicle is locked or unlocked, the electronic control unit wakes up to start the operation in response to the door signal provided from the door of the vehicle.

In this case, the door signal generated when the door of the vehicle is locked may be composed of two pulses of short duty, and the door signal generated when the door of the vehicle is unlocked may be composed of two pulses of long duty .

In this case, the electronic control unit may start the operation in response to the first pulse of the door signal, and may determine whether the door is locked or unlocked by detecting the length of the second pulse.

However, depending on the situation, if the electronic control wakes up longer than the time between the first pulse and the second pulse, the electronic controller may not be able to sense the second pulse and thus may not determine whether the door is locked or unlocked.

The first transistor 100 is turned on and off in response to the door signal to pull up the first node.

At this time, the first transistor 100 can be turned on to pull up the first node when the door signal is low level.

That is, when the door signal transmits a pulse, the first transistor 100 is turned off and does not pull up the first node, while the door signal goes before the first pulse, between the first pulse and the second pulse, If it is in a state after the pulse, the first transistor 100 is turned on to pull up the first node.

The first capacitor 200 supplies a charge to the first node when the first transistor 100 is off.

At this time, the first capacitor may be connected between the first node and ground.

That is, the first capacitor is charged according to the potential of the pulled-up first node when the door signal is at the low level, and when the door signal transmits the pulse, the potential of the first node falls, but by the charge supplied by the first capacitor , And falls at a reduced speed. After a certain period of time, when the capacity of the first capacitor is exhausted, the potential of the first node drops more rapidly.

The operational amplifier 400 compares the potential of the first node with the reference voltage to generate a pulse signal.

At this time, the operational amplifier 400 can generate a pulse signal when the potential of the first node is lower than the reference voltage.

The reference voltage generator 300 provides a reference voltage to the operational amplifier 400.

In this case, the reference voltage generator 300 may be a voltage distributor connected between the power source and the ground.

For example, the reference voltage generator 300 shown in FIG. 1 provides a voltage suitable for the plus side input of the operational amplifier 400 as a voltage divider composed of two resistors.

At this time, an appropriate voltage is a voltage lower than the potential drop of the first node while the first node is pulled up when the first node is pulled up and the door is locked when the first node is pulled up, Can be set to a voltage higher than the limit of the potential drop of the first node while one node is not pulled up.

Therefore, the operational amplifier 400 does not generate a pulse signal when the door signal transmits two pulses generated when the door is locked, but generates a pulse signal when the door transmits two pulses generated when the door is unlocked can do.

Here, the reference voltage generating section 300 may be constituted by a circuit which is shown as a voltage distributing device composed of two resistors but supplies a suitably predetermined constant voltage which is implemented by another method.

The pulse retry rejection 500 retriggers the pulse signal and outputs a signal with a delayed pulse width.

As described above, when the operational amplifier 400 generates a pulse signal, the duty of the pulse becomes shorter than the length of the second pulse of the door signal, so that it may be a length not enough for the electronic control unit to detect.

Therefore, the pulse retry rejection unit 500 can retrigger the pulse signal generated by the operational amplifier 400 and supply a signal delayed by the pulse width, thereby judging whether the electronic control unit is correctly locked or unlocked .

FIG. 2 is a diagram illustrating a potential of a first node, a door signal, and an output of an operational amplifier according to an embodiment of the present invention.

As described above, when the door signal is at the low level, the first node is pulled up by the first transistor 100, so that the potential of the first node exceeds the reference voltage, so that the operational amplifier 400 outputs the pulse signal The output of the operational amplifier 400 remains at the low level. Also, the first capacitor 200 is charged during this period.

The duty of the first and second pulses included in the door signal is smaller than when the door is unlocked.

In this case, the potential of the first node is lowered while the first transistor 100 is turned off by the first and second pulses. At this time, however, the potential drop of the first capacitor 200 is still lowered by the charge charged in the first capacitor 200, so that the potential of the first node does not fall below the reference voltage until all of the first capacitor 200 is discharged .

Also, when the duty of each of the first and second pulses ends and the level of the door signal becomes a low level again, the first transistor 100 is pulled up, so that the potential of the first node rises.

Therefore, when the door is locked, the potential of the first node does not fall below the reference voltage, so that the output of the operational amplifier 400 stays at a low level.

On the other hand, when the door is unlocked, the duty of the first and second pulses included in the door signal is larger than when the door is locked.

In this case, the potential of the first node is lowered while the first transistor 100 is turned off by the first and second pulses.

Also, the potential drop rate is slowed by the charge charged in the first capacitor 200 while the potential of the first node is falling, and the charges of the first capacitor 200 during the duty of the first and second pulses are all discharged .

Therefore, in this case, after all of the first capacitors 200 are discharged, the potential of the first node falls below the reference voltage.

Thus, the operational amplifier 400 outputs a pulse signal while the potential of the first node falls below the reference voltage.

Accordingly, when the door is unlocked, the operational amplifier 400 generates a pulse signal in response to the door signal.

The pulse retry rejection unit 500 can retrigger the pulse signal generated by the operational amplifier 400 to delay the pulse width so that the electronic control unit can judge whether the door is locked or unlocked.

3 is a flowchart illustrating an operation of an electronic control unit wake-up signal generating method for detecting pulse duty according to an embodiment of the present invention. A method of managing a vehicle damage using an electronic control unit wake-up signal generating method for detecting pulse duty will be described.

First, the first transistor 100 pulls up the potential of the first node in response to the door signal (S110).

As described above, when the door signal is at the low level, the first transistor 100 is turned on and the potential of the first node can be pulled up.

On the other hand, when the door signal transmits a pulse, the first transistor 100 does not pull up the potential of the first node, so that the potential of the first node falls. The falling of the potential of the first node is delayed by the charge charged in the first capacitor 200 when the first transistor 100 does not pull up the potential of the first node.

Thereafter, the operational amplifier 400 determines whether the potential of the first node is lower than the reference voltage (S120).

At this time, if the potential of the first node drops below the reference voltage, the operational amplifier 400 generates a pulse signal (S130) and ends the process.

As described above, when the potential of the first node falls below the reference voltage, the first transistor 100 is turned off for a sufficiently long time, and the potential of the first node is not pulled up during that time, The potential of the first node can not be sufficiently delayed by the capacitance of the charge charged in the first node.

The first transistor 100 is turned off when the door signal is at a high level, that is, when a pulse is transmitted. Therefore, when the door having the longer duty cycle of the pulse of the door signal is unlocked, 400 may be turned off long enough to generate a pulse signal.

In this case, in step S130, the pulse retry rejection unit 500 may retrigger the pulse signal generated by the operational amplifier 400 and output a signal delayed in pulse width.

Therefore, when the door is unlocked, the pulse retry rejection unit 500 outputs a signal delayed by the pulse width, so that the electronic control unit can accurately determine that the door is unlocked.

If the operational amplifier 400 determines in step S120 that the potential of the first node is not lower than the reference voltage, the operational amplifier 400 outputs a signal in which a low level is maintained (S140) and ends the process.

Therefore, when the door is locked and when the door is unlocked, the output of the operational amplifier 400 maintains the low level when the middle door signal is at the low level.

Accordingly, the electronic control unit can determine that the door is unlocked only when the operational amplifier 400 and the pulse retry rejection unit 500 output the pulse signal.

As described above, according to the present invention, when a door signal generated when a door is unlocked and a door signal generated when a door is locked is detected, a pulse signal is generated when the door is unlocked, Even when the electronic control unit takes a long time to wake up, it is possible to accurately distinguish the door signal when the door is locked and the door signal when the door is unlocked.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the technical scope of the present invention should be defined by the following claims.

100: first transistor 200: first capacitor
300: reference voltage generator 400: operational amplifier
500: Pulse retry reject

Claims (12)

A first transistor that is turned on and off in response to a door signal to pull up a first node;
A first capacitor for supplying electric charge to the first node when the first transistor is off;
An operational amplifier for comparing a potential of the first node with a reference voltage to generate a pulse signal; And
And a reference voltage generator for providing the reference voltage to the operational amplifier.
The method according to claim 1,
Further comprising pulse retry rejection for retriggering the pulse signal to output a signal delayed in pulse width.
The method according to claim 1,
Wherein the first transistor is turned on to pull up the first node when the door signal is at a low level.
The method according to claim 1,
Wherein the first capacitor is coupled between the first node and ground. ≪ Desc / Clms Page number 21 >
The method according to claim 1,
Wherein the reference voltage generator is a voltage divider connected between a power supply and a ground.
The method according to claim 1,
The reference voltage is lower than the potential drop threshold of the first node while the first node is not pulled up when the door of the vehicle is locked and the potential of the first node while the first node is not pulled up when the door of the vehicle is unlocked Wherein the voltage is higher than a lower limit of the voltage drop.
The method according to claim 1,
Wherein the operational amplifier generates a pulse signal when the potential of the first node is lower than the reference voltage.
The first transistor pulling up the potential of the first node in response to the door signal;
The operational amplifier comparing a potential of the first node with a reference voltage; And
And wherein the operational amplifier generates a pulse signal when the potential of the first node is less than the reference voltage.
9. The method of claim 8,
In the step of generating the pulse signal,
Wherein the pulse retry rejection retrigger the pulse signal generated by the operational amplifier to output a signal delayed in pulse width.
9. The method of claim 8,
In the step of pulling up the first node,
Wherein the first transistor is turned on to pull up the first node when the door signal is at a low level.
9. The method of claim 8,
The reference voltage is lower than the potential drop threshold of the first node while the first node is not pulled up when the door of the vehicle is locked and the potential of the first node while the first node is not pulled up when the door of the vehicle is unlocked Wherein the voltage duty ratio is higher than a lower limit of the duty cycle.
9. The method of claim 8,
Wherein the operational amplifier outputs a low level signal when the potential of the first node is not lower than the reference voltage.

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