JP2008082284A - On-vehicle apparatus control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an on-vehicle apparatus control device capable of suppressing loss of drive energy of an on-vehicle apparatus in starting an engine, and of sufficiently extracting the performance of the on-vehicle apparatus. <P>SOLUTION: This on-vehicle apparatus control device is provided with: a portable appliance 2 carried by a user of a vehicle 1; an on-vehicle communication instrument 12 provided for the vehicle 1 and communicating with the portable appliance 2; a startup starting time calculation means 17 provided for the vehicle 1, and calculating a startup starting time at which a driver starts the engine startup of the vehicle 1 according to the communication result by communication between the portable appliance 2 and the on-vehicle communication instrument 12; and an on-vehicle apparatus continuous control means 13 starting predetermined drive of the on-vehicle apparatus of the vehicle 1 according to the startup starting time. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an in-vehicle device control apparatus for controlling an in-vehicle device of a vehicle prior to starting of an engine of the vehicle in accordance with a communication result between a portable device carried by a user of the vehicle and a communication means provided in the vehicle. About.

  A conventional automotive electronic control device includes a microcomputer that controls an on-vehicle device and a power supply circuit that supplies power to the microcomputer. Even when the ignition switch of the automobile is disconnected, a circuit other than the ignition switch The power supply circuit is changed from an inactive state to an active state that generates a voltage for operating the microcomputer by the wake-up signal, thereby starting the microcomputer and executing a predetermined process (for example, a patent) Reference 1).

FIG. 5 is a block diagram showing the automobile electronic control device described in Patent Document 1. In FIG.
In FIG. 5, the automobile electronic control device includes a vehicle 51 and a portable device 52 carried by the driver of the vehicle 51.
The portable device 52 includes a push button switch 53 used for an operation of unlocking the door lock of the vehicle 51, and a transmitter 54 that transmits an unlock code signal by the operation of the push button switch 53.

  When the vehicle 51 authenticates that the unlocking code signal transmitted from the transmitter 54 is received through the antenna 55 and the received unlocking code signal is genuine, the vehicle 51 A microcomputer 59 for outputting a door lock unlocking signal for unlocking the door lock 57 to the door lock control means 58; and a door lock control means 58 for unlocking the door lock 57 in response to the door lock unlocking signal. Contains.

  The vehicle 51 includes an engine 60, a fuel pump 61 (on-vehicle equipment) that supplies fuel to the engine 60, a fuel tank 62 that stores fuel supplied to the engine 60 by the fuel pump 61, a fuel tank 62, and fuel. It further includes a fuel line 63 that transports fuel between the pump 61 and between the fuel pump 61 and the engine 60.

Here, when outputting a door lock unlocking signal to the door lock control means 58, the microcomputer 59 outputs a drive signal for starting driving to the fuel pump 61 prior to starting the engine 60.
In addition, the microcomputer 59 outputs the door lock unlocking signal to the door lock control means 58 to an air flow sensor, oxygen sensor, and various heaters (not shown) that are part of the vehicle equipment. A drive signal for driving all or part of the signal is output.

  A conventional fuel pump drive control device for a vehicle engine detects a driver's intention to drive the fuel pump (fuel pump) before starting the engine operation in a vehicle engine equipped with a fuel injection device. In addition, there is a control means for stopping the driving of the fuel pump after a predetermined time has elapsed after the driving of the fuel pump has started (see, for example, Patent Document 2).

FIG. 6 is a block diagram showing the fuel pump drive control device described in Patent Document 2.
In FIG. 6, the fuel pump drive control device replaces the portable device 52, antenna 55, receiver 56, door lock 57, and door lock control means 58 shown in FIG. The vehicle includes a sensor that detects that the door has been opened or that the driver is seated in the driver's seat, and includes driving intention detection means 64 that detects the intention of the driver to drive.

The fuel pump drive control device further includes a fuel pressure sensor 65 that detects the fuel pressure in the fuel line 63 from the fuel pump 61 to the engine 60.
The microcomputer 59 outputs a drive signal for starting driving prior to the start of the engine 60 to the fuel pump 61 when the driving intention detection unit 64 detects the driving intention of the driver. Further, the microcomputer 59 outputs a stop signal for stopping the fuel pump 61 when the fuel pressure detected by the fuel pressure sensor 65 reaches a predetermined value.

  Further, the conventional fuel supply device for an internal combustion engine has a configuration in which the fuel in the fuel tank is pumped up by an electric low pressure fuel pump, and when the start operation of the internal combustion engine is detected, the cranking of the internal combustion engine is started prior to the start. Then, the driving of the low-pressure fuel pump is started (for example, see Patent Document 3).

FIG. 7 is a block diagram showing the fuel supply device described in Patent Document 3.
In FIG. 7, this fuel supply apparatus includes an ignition switch 66 for starting the internal combustion engine by the driver of the vehicle 51, instead of the driving intention detection means 64 shown in FIG.
When the ignition switch 66 is operated, the microcomputer 59 outputs a drive signal for starting driving to the fuel pump 61 prior to the start of cranking. Further, the microcomputer 59 changes the drive time of the fuel pump 61 according to the fuel pressure detected by the fuel pressure sensor 65.

JP 2004-197585 A Japanese Utility Model Publication No. 58-127171 JP 2004-92447 A

In the conventional automotive electronic control device described in Patent Document 1, the driver operates the push button switch 53 to unlock the door lock 57, and the fuel pump 61, sensors, Alternatively, a drive signal is output to the heaters.
Here, when the driver operates the push button switch 53 at a location far away from the door, it takes a long time from when the door lock 57 is unlocked (the vehicle-mounted device is driven) until the engine 60 is started. May elapse, and the drive time of the fuel pump 61 and the like that are driven prior to the start of the engine 60 may become longer.
Therefore, when the engine 60 is started, the drive time of the fuel pump 61 and the like is already excessive, and as a result, there is a problem that the drive energy of the in-vehicle device such as the fuel pump 61 is wasted.

In addition, when the driver operates the push button switch 53 in the immediate vicinity of the door, the time from when the door lock 57 is unlocked (when the in-vehicle device is driven) until the engine 60 is started is shortened. The drive time of the fuel pump 61 or the like that is driven prior to starting 60 may be shortened.
Therefore, when the engine 60 is started, the fuel pressure boosted by the fuel pump 61 may not rise sufficiently. In addition, the operation of the sensors may not be stable, or the temperature of the heaters may not increase and desired performance may not be obtained.
That is, when the engine 60 is started, there is a problem in that the performance of the in-vehicle device cannot be sufficiently obtained.

Further, in the conventional fuel pump drive control device described in Patent Document 2, it is detected by the driving intention detection means 64 that the driver has opened the door of the vehicle 51 or that the driver has been seated in the driver's seat. In this case, a drive signal is output to the fuel pump 61, sensors, or heaters that are on-vehicle equipment.
Therefore, the time from when the vehicle-mounted device is driven to when the engine 60 is started is shorter than when the driver operates the push button switch 53 in the vicinity of the door in Patent Document 1, and prior to starting the engine 60. In some cases, the driving time of the fuel pump 61 or the like driven by the motor is further shortened.
For this reason, when the engine 60 is started, there is a problem that the performance of the fuel pump 61, sensors, or heaters that are on-vehicle equipment cannot be sufficiently obtained.

Further, in the conventional fuel supply device for an internal combustion engine described in Patent Document 3, when a driver operates the ignition switch 66, a drive signal is supplied to the fuel pump 61, sensors, or heaters that are on-vehicle equipment. Is output.
Therefore, the time from when the in-vehicle device is driven to when cranking starts is shorter than that in the case of Patent Document 2, and the driving time of the fuel pump 61 and the like that is driven prior to the start of cranking is further shortened. There is a case.
For this reason, when cranking is started, there is a problem that the performance of the fuel pump 61, sensors, or heaters that are on-vehicle equipment cannot be fully exploited.

  An object of the present invention is to solve the above-described problems, and an object of the present invention is to suppress the waste of driving energy of the in-vehicle device and to sufficiently improve the performance of the in-vehicle device when starting the engine. It is in providing the vehicle equipment control apparatus which can be pulled out.

  An in-vehicle device control apparatus according to the present invention includes a portable device carried by a user of a vehicle, communication means provided in the vehicle and communicating with the portable device, and communication performed by communication between the portable device and the communication means provided in the vehicle. Start start time calculating means for calculating a start start time for the user to start engine start of the vehicle according to the result, and in-vehicle device continuous control for starting driving a predetermined in-vehicle device of the vehicle according to the start start time Means.

According to the in-vehicle device control apparatus of the present invention, the start start time calculating means calculates the start start time when the user starts the engine start of the vehicle according to the communication result by communication between the portable device and the communication means, The in-vehicle device continuous control means starts driving a predetermined in-vehicle device of the vehicle according to the start start time.
Therefore, when starting the engine, it is possible to suppress the waste of drive energy of the in-vehicle device and to sufficiently bring out the performance of the in-vehicle device.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding members and parts will be described with the same reference numerals.

Embodiment 1 FIG.
1 is a block diagram showing an in-vehicle device control system of an in-vehicle device control apparatus according to Embodiment 1 of the present invention.
In FIG. 1, the in-vehicle device control system includes a vehicle 1 and a portable device 2 carried by a driver (user) of the vehicle 1.

The portable device 2 receives the portable device search signal (described later) from the in-vehicle communication device 12 (described later), and unlocks the door lock of the vehicle 1 in response to the reception of the portable device search signal. And a transmitter 4 for transmitting the unlocking code signal.
The portable device 2 further includes a microprocessor (not shown) having a CPU and a memory storing a program, and an unlock code signal including an individual identification code that differs for each portable device is stored in the memory in advance. Yes.

The vehicle 1 includes an in-vehicle device control unit 5, a door lock control means 6, a door lock 7, an engine 8, a fuel pump 9 (on-vehicle device), a fuel tank 10, and fuel lines 11D and 11E. Yes.
The in-vehicle device control unit 5 includes an in-vehicle communication device (communication means) 12 that communicates with the portable device 2, and a door lock control means 6 and a fuel pump 9 according to a communication result by communication between the portable device 2 and the in-vehicle communication device 12. And a microcomputer 13 for controlling the control.

The door lock control means 6 unlocks or locks the door lock 7 in response to a command signal from the microcomputer 13.
The fuel pump 9 supplies fuel to the engine 8. The fuel tank 10 stores fuel supplied to the engine 8 by the fuel pump 9. The fuel line 11 </ b> D transports fuel between the fuel pump 9 and the engine 8. The fuel line 11 </ b> E transports fuel between the fuel tank 10 and the fuel pump 9.

The in-vehicle communication device 12 includes a portable device search signal transmission means 14 for transmitting a portable device search signal for searching for the portable device 2, and an unlocking signal transmitted from the transmitter 4 of the portable device 2 according to the portable device search signal. It has an unlocking code signal receiving means 15 for receiving a code signal, and an antenna 16 for transmitting and receiving a portable device search signal and an unlocking code signal.
The in-vehicle communication device 12 further includes a microprocessor (not shown) having a CPU and a memory storing a program, and the portable device search signal is stored in the memory in advance.
The in-vehicle communication device 12 estimates the distance between the portable device 2 (driver) and the antenna 16 (vehicle 1) based on the unlock code signal received by the unlock code signal receiving means 15, and An output signal including the unlocking code signal is output to the microcomputer 13 as a communication result by communication with the portable device 2.

The microcomputer 13 includes a start start time calculating unit 17 that calculates a start start time for the driver to start the engine of the vehicle 1 according to a communication result between the portable device 2 and the in-vehicle communication device 12, and the calculated start In-vehicle equipment continuous control means 18 for outputting a drive signal for starting driving prior to the start of the engine 8 to the fuel pump 9 according to the start time.
Here, the microcomputer 13 is constituted by a microprocessor (not shown) having a CPU and a memory storing a program.

Further, the microcomputer 13 authenticates the unlocking code signal included in the output signal from the in-vehicle communication device 12, and outputs a command signal for unlocking or locking the door lock 7 based on the authentication result. 6 is output. Authentication of the unlocking code signal is executed by comparing the individual identification code included in the unlocking code signal with the individual identification code for authentication stored in advance in the memory of the microcomputer 13.
The microcomputer 13 is driven by a battery power source (not shown), and operates the vehicle 1, the engine 8, and the engine 8 based on information input from various sensors (not shown) via each interface. Various actuators (not shown) including functions and various in-vehicle devices are controlled.

Hereinafter, the operation of the in-vehicle device control apparatus according to Embodiment 1 of the present invention will be described with reference to FIG.
First, in the operation of authenticating the unlocking code signal transmitted from the transmitter 4 of the portable device 2 and unlocking or locking the door lock 7, the operation of unlocking from the state where the door lock 7 is locked Will be described.

First, it is assumed that driving of the vehicle 8 such as the engine 8 and the fuel pump 9 is stopped, the vehicle 1 is parked, and the door lock 7 is locked.
At this time, the portable device search signal transmission means 14 of the in-vehicle communication device 12 transmits a portable device search signal for searching for the portable device 2 through the antenna 16 every arbitrary predetermined time.
The portable device 2 does not perform any operation unless it receives the portable device search signal.
Therefore, when the portable device 2 does not exist in an area where the portable device search signal can be received (hereinafter referred to as “covering area of the portable device search signal”), the in-vehicle communication device 12 transmits the portable device search signal. Just do not do anything else.

Subsequently, when the driver carrying the portable device 2 enters the coverage area of the portable device search signal, the receiver 3 of the portable device 2 receives the portable device search signal, and the transmitter 4 receives the unlock code signal. send.
The unlock code signal receiving means 15 of the in-vehicle communication device 12 receives the unlock code signal from the transmitter 4 via the antenna 16.
The in-vehicle communication device 12 estimates the distance between the portable device 2 and the vehicle 1 based on the unlocking code signal, and outputs an output signal including the distance and the unlocking code signal as a communication result by communication with the portable device 2. The data is output to the microcomputer 13.

The microcomputer 13 compares the individual identification code included in the unlocking code signal included in the output signal from the in-vehicle communication device 12 with the individual identification code for authentication stored in advance in the memory.
If both the individual identification codes match, the microcomputer 13 determines that the driver carrying the portable device 2 is a driver who may use the vehicle 1 and controls the door lock. A command signal for unlocking the door lock 7 is output to the means 6.
The door lock control means 6 unlocks the door lock 7 in response to a command signal for unlocking the door lock 7.

  Further, the microcomputer 13 determines that the driver carrying the portable device 2 is a driver who should not use the vehicle 1 when the two individual identification codes do not match, and the door No command signal is output to the lock control means 6, and the door lock 7 is kept locked.

Here, since the portable device search signal transmission means 14 of the in-vehicle communication device 12 transmits the portable device search signal every predetermined time, the portable device 2 is portable as long as it exists in the coverage area of the portable device search signal. A machine search signal is received and an unlock code signal is transmitted.
That is, the portable device 2 transmits an unlocking code signal every predetermined time as long as the portable device 2 exists at a position closer to the antenna 16 than the position at which the portable device search signal is first received. The unlocking code signal receiving means 15 of the in-vehicle communication device 12 receives the unlocking code signal every predetermined time, and the microcomputer 13 receives the unlocking code signal from the in-vehicle communication device 12 every predetermined time.

At this time, since the microcomputer 13 determines that the driver carrying the portable device 2 is a driver who may use the vehicle 1 every predetermined time, no command signal is sent to the door lock control means 6. No output is made and the door lock 7 is kept unlocked.
Therefore, as long as the driver carrying the portable device 2 enters the coverage area of the portable device search signal and the portable device 2 exists in the coverage area of the portable device search signal, the unlocked door lock 7 is unlocked. The maintained state is maintained.

Next, an operation of locking the door lock 7 from the unlocked state will be described.
First, it is assumed that the driver carrying the portable device 2 is present in the coverage area of the portable device search signal, and the door lock 7 is kept unlocked.
Here, when the driver carrying the portable device 2 moves out of the coverage area of the portable device search signal, the portable device 2 cannot receive the portable device search signal and therefore does not transmit the unlock code signal.
Therefore, the unlock code signal receiving means 15 of the in-vehicle communication device 12 does not receive the unlock code signal, and the microcomputer 13 does not receive the unlock code signal from the in-vehicle communication device 12.

When the microcomputer 13 stops receiving the unlock code signal from the in-vehicle communication device 12 while the door lock 7 is kept unlocked, the driver carrying the portable device 2 holds the vehicle 1. A command signal for locking the door lock 7 to the door lock control means 6 when it is determined that the driver is not in use or the driver carrying the portable device 2 is present at a position where the vehicle 1 is not used. Is output.
The door lock control means 6 locks the door lock 7 in response to a command signal for locking the door lock 7.
That is, the microcomputer 13 determines that the driver carrying the portable device 2 is in a state where the vehicle 1 is not used, or that the driver carrying the portable device 2 is present at a position where the vehicle 1 is not used. In this case, the door lock 7 is kept locked.

In the operation in which the door lock 7 is unlocked or locked, the communication between the portable device 2 and the in-vehicle communication device 12 is performed without the driver of the vehicle 1 performing any active operation on the portable device 2. Executed.
The door lock 7 is unlocked or locked according to a communication result by communication between the portable device 2 and the in-vehicle communication device 12.

Next, the operation in which the in-vehicle communication device 12 estimates the distance between the portable device 2 and the antenna 16 (vehicle 1) based on the unlock code signal received by the unlock code signal receiving means 15 will be described.
Here, since communication between the portable device 2 and the in-vehicle communication device 12 can be executed using radio waves, the distance between the portable device 2 and the vehicle 1 is estimated based on the following distance measurement principle. Can do.
First, since it is known that the strength of the radio wave is inversely proportional to the square of the distance, the in-vehicle communication device 12 determines the distance between the portable device 2 and the vehicle 1 by measuring the radio wave strength of the unlocking code signal. Can be estimated.

Further, when the radio wave intensity of the portable machine search signal transmitted from the portable machine search signal transmission means 14 and the radio wave intensity of the unlocking code signal transmitted from the transmitter 4 are respectively fixed to arbitrary predetermined strengths. When the portable device search signal transmission means 14 transmits the portable device search signal and the unlocking code signal reception means 15 receives the unlocking code signal from the transmitter 4, the in-vehicle communication device 12 can be more easily transmitted. The distance between the portable device 2 and the vehicle 1 can be estimated.
That is, when the radio field intensity of the portable device search signal is stronger than the radio field intensity of the unlocking code signal, the distance at which the unlocking code signal receiving means 15 can receive the unlocking code signal is determined between the portable device 2 and the vehicle 1. It can be estimated as a distance. Further, when the radio wave intensity of the unlocking code signal is stronger than the radio wave intensity of the portable device search signal, the distance that the receiver 3 of the portable device 2 can receive the portable device search signal is set to a distance between the portable device 2 and the vehicle 1. It can be estimated as a distance.

In addition, when the radio field intensity of the portable device search signal transmitted from the portable device search signal transmission unit 14 and the radio field intensity of the unlocking code signal transmitted from the transmitter 4 are respectively fixed to predetermined strengths as described above. In other words, the in-vehicle communication device 12 measures the radio wave intensity of the unlocking code signal, and measures the attenuation with respect to the fixed predetermined intensity, thereby estimating the distance between the portable device 2 and the vehicle 1.
At this time, as described above, the attenuation of the radio field intensity is inversely proportional to the square of the distance.

Here, as described above, the portable device search signal transmission means 14 transmits the portable device search signal every predetermined time.
Therefore, every time the unlocking code signal receiving means 15 receives the unlocking code signal, the in-vehicle communication device 12 estimates the distance between the portable device 2 and the vehicle 1, so that the portable device search signal transmitting means 14 becomes the portable device. The distance between the portable device 2 and the vehicle 1 is estimated every predetermined time for transmitting the search signal.
The in-vehicle communication device 12 outputs an output signal including the estimated distance between the portable device 2 and the vehicle 1 and the unlocking code signal to the microcomputer 13 as a communication result by communication with the portable device 2.

Next, an operation in which the start start time calculating unit 17 calculates the start start time at which the driver starts starting the engine of the vehicle 1 according to the communication result between the portable device 2 and the in-vehicle communication device 12 will be described.
First, the start time calculating means 17 divides the distance between the portable device 2 and the vehicle 1 included in the output signal from the in-vehicle communication device 12 by the walking speed of the driver, so that the driver arrives at the vehicle 1. Calculate the time until. The driver's walking speed is assumed to be an average speed and is stored in advance in the memory of the microcomputer 13 or is described in a program stored in the memory.

Subsequently, the start start time calculating means 17 adds the time until the driver arrives at the vehicle 1 and starts the engine start to the time until the driver arrives at the vehicle 1, Every time the search signal transmission means 14 transmits the portable device search signal, the start time for starting the engine of the vehicle 1 by the driver is calculated.
Here, the time from when the driver arrives at the vehicle 1 to start the engine starts is from when the driver arrives at the vehicle 1 until the driver opens the door, sits in the driver's seat, and starts the engine. Time, and can be assumed as an average time. The time from when the driver arrives at the vehicle 1 to start the engine is stored in advance in the memory of the microcomputer 13 or described in a program stored in the memory.

Next, an operation in which the in-vehicle device continuous control means 18 starts driving the fuel pump 9 according to the calculated start time will be described.
The on-vehicle equipment continuous control means 18 sends the engine to the fuel pump 9 when the start start time calculated by the start start time calculation means 17 coincides with the drive start time stored in the memory of the microcomputer 13 in advance. Prior to the start of 8, a drive signal for starting the drive is output.
Here, the drive start time indicates the time required for the fuel pressure of the fuel supplied to the engine 8 to reach the fuel pressure at which the engine 8 can be started satisfactorily.
Note that when the engine start is started in a time shorter than the start start time, the drive start time may be set longer than the above required time in order to prevent the fuel pressure from being insufficient.

In the above description, the on-vehicle equipment continuous control means 18 outputs a drive signal to the fuel pump 9, but the present invention is not limited to this.
The vehicle 1 further includes an air flow sensor, an oxygen sensor, and various heaters (not shown) as in-vehicle devices, and the in-vehicle device continuous control means 18 has a start start time calculated by the start start time calculation means 17 in the microcomputer 13. When the driving start time stored in advance in the memory coincides, a driving signal for starting driving prior to the start of the engine 8 is output to the airflow sensor, oxygen sensor, and various heaters in the same manner as the fuel pump 9. To do.
Here, the drive start time is set for each different time according to the type of the in-vehicle device, and is stored in the memory of the microcomputer 13.

According to the in-vehicle device control apparatus according to Embodiment 1 of the present invention, the start start time calculating means 17 causes the driver to start the engine of the vehicle 1 according to the communication result between the portable device 2 and the in-vehicle communication device 12. The start start time to be started is calculated, and the in-vehicle device continuous control means 18 starts driving the in-vehicle device according to the calculated start start time.
That is, when the driver carrying the portable device 2 approaches the vehicle 1 to be used, the drive of the vehicle-mounted device is started prior to the start of the engine 8 by the drive signal from the vehicle-mounted device continuous control means 18. After the drive start time has elapsed from the start, the driver starts the engine start.
Therefore, when the engine 8 is started, the driving time of the in-vehicle device becomes excessive, the driving energy of the in-vehicle device is not wasted, and the driving energy of the in-vehicle device can be made a consumption amount that is not excessive or insufficient.
In addition, the drive time of the in-vehicle device is shortened, the fuel pressure of the fuel supplied to the engine 8 is insufficient, the operation of the sensors becomes unstable, the temperature rise of the heaters is insufficient, There is no inconvenience that the performance of the in-vehicle device is not sufficiently exhibited, and the in-vehicle device can be put into a suitable operating state before the engine 8 is started.
Furthermore, since the fuel pressure is suitable and the startability of the engine 8 is improved and the operation of the sensors and heaters is improved, the control performance of the control system using these sensors and heaters is improved. Can be.

Embodiment 2. FIG.
In the first embodiment, the time required for the driver to arrive at the vehicle 1 is calculated using the walking speed of the driver assumed as an average speed. However, the present invention is not limited to this.
The walking speed of the driver may be calculated based on the distance between the portable device 2 and the vehicle 1 included in the output signal from the in-vehicle communication device 12.

Since the configuration of the in-vehicle device control system of the in-vehicle device control apparatus according to Embodiment 2 of the present invention is the same as that in Embodiment 1 above, description thereof is omitted.
The start start time calculating means 17 calculates the driver's walking speed based on the distance between the portable device 2 and the vehicle 1 included in the output signal from the in-vehicle communication device 12, and the in-vehicle communication with the portable device 2. The start time for the driver to start the engine of the vehicle 1 is calculated according to the communication result with the machine 12 and the calculated walking speed of the driver.

Hereinafter, the operation of the in-vehicle device control apparatus according to Embodiment 2 of the present invention will be described with reference to FIG.
Note that the description of the same operation as in the first embodiment is omitted.
First, an operation in which the start start time calculating unit 17 calculates the driver's walking speed based on the distance between the portable device 2 and the vehicle 1 included in the output signal from the in-vehicle communication device 12 will be described.

First, based on the unlocking code signal received by the unlocking code signal receiving unit 15, the in-vehicle communication device 12 uses the portable unit search signal transmitting unit 14 to transmit the portable unit search signal as shown in the first embodiment. The distance between the portable device 2 and the vehicle 1 is estimated every predetermined time for transmission.
The in-vehicle communication device 12 outputs an output signal including the estimated distance between the portable device 2 and the vehicle 1 and the unlocking code signal to the microcomputer 13 as a communication result by communication with the portable device 2.

The start time calculation means 17 calculates the walking speed of the driver based on the distance traveled by the driver during a predetermined time when the portable device search signal transmission means 14 transmits the portable device search signal.
That is, the start time calculation means 17 calculates the difference in distance between the portable device 2 and the vehicle 1 estimated every predetermined time when the portable device search signal transmission means 14 transmits the portable device search signal. The driver's walking speed is calculated by dividing by a predetermined time to be transmitted.

  The start time calculation means 17 stores the time when the output signal including the distance between the portable device 2 and the vehicle 1 is input from the in-vehicle communication device 12, and the output signal from the in-vehicle communication device 12 is twice. Every time it is input, the difference in distance between the portable device 2 and the vehicle 1 and the difference in time when the output signal from the in-vehicle communication device 12 is input are calculated, and the calculated difference in distance is calculated. The driver's walking speed may be calculated by dividing by the difference.

Next, the start start time calculating means 17 starts the driver starting the engine of the vehicle 1 according to the communication result between the portable device 2 and the vehicle-mounted communication device 12 and the calculated walking speed of the driver. An operation for calculating the start time will be described.
First, the start start time calculating means 17 divides the distance between the portable device 2 and the vehicle 1 included in the output signal from the in-vehicle communication device 12 by the calculated walking speed of the driver, so that the driver The time until arrival at 1 is calculated.

Subsequently, the start start time calculating means 17 adds the time until the driver arrives at the vehicle 1 and starts the engine start to the time until the driver arrives at the vehicle 1, Every time the search signal transmission means 14 transmits the portable device search signal or every time the driver's walking speed is calculated, a start start time for the driver to start the engine of the vehicle 1 is calculated.
Here, the time from when the driver arrives at the vehicle 1 to start the engine starts is from when the driver arrives at the vehicle 1 until the driver opens the door, sits in the driver's seat, and starts the engine. Time, and can be assumed as an average time.
The time from when the driver arrives at the vehicle 1 to start the engine may be a time estimated in correlation with the calculated walking speed of the driver.

  Next, as shown in the first embodiment, the in-vehicle device continuous control means 18 uses the drive start time stored in advance in the memory of the microcomputer 13 as the start start time calculated by the start start time calculating means 17. In the case of coincidence, a driving signal for starting driving is output to the fuel pump 9 prior to starting of the engine 8.

In the above description, the on-vehicle equipment continuous control means 18 outputs a drive signal to the fuel pump 9, but the present invention is not limited to this.
As shown in the first embodiment, the vehicle 1 further includes an airflow sensor, an oxygen sensor, and various heaters (not shown) as in-vehicle devices, and the in-vehicle device continuous control means 18 is calculated by the start start time calculating means 17. When the started start time coincides with the drive start time stored in advance in the memory of the microcomputer 13, the engine 8 is started with respect to the air flow sensor, the oxygen sensor, and various heaters similarly to the fuel pump 9. Prior to this, a drive signal for starting driving is output.

According to the in-vehicle device control apparatus according to Embodiment 2 of the present invention, the start start time calculating means 17 causes the driver to start the engine of the vehicle 1 according to the communication result between the portable device 2 and the in-vehicle communication device 12. The start start time to be started is calculated, and the in-vehicle device continuous control means 18 starts driving the in-vehicle device according to the calculated start start time.
That is, when the driver carrying the portable device 2 approaches the vehicle 1 to be used, the drive of the vehicle-mounted device is started prior to the start of the engine 8 by the drive signal from the vehicle-mounted device continuous control means 18. After the drive start time has elapsed from the start, the driver starts the engine start.
Here, the start start time calculating means 17 calculates the driver's walking speed based on the distance between the portable device 2 and the vehicle 1 included in the output signal from the in-vehicle communication device 12, and the calculated driver's walking Since the start start time is calculated using the speed, the start start time can be calculated with higher accuracy than in the case of the first embodiment.
Therefore, when the engine 8 is started, the driving time of the in-vehicle device becomes excessive, the driving energy of the in-vehicle device is not wasted, and the driving energy of the in-vehicle device can be further reduced to a consumption amount that is not excessive or insufficient. .
In addition, the drive time of the in-vehicle device is shortened, the fuel pressure of the fuel supplied to the engine 8 is insufficient, the operation of the sensors becomes unstable, the temperature rise of the heaters is insufficient, There is no inconvenience that the performance of the in-vehicle device is not sufficiently exhibited, and the in-vehicle device can be brought into a more preferable operating state before the engine 8 is started.
Furthermore, since the fuel pressure is suitable and the startability of the engine 8 is improved, and the operations of the sensors and heaters are improved, the control performance of the control system using these sensors and heaters is further improved. Can be good.

Embodiment 3 FIG.
In the first embodiment, the fuel pump 9, the sensors, and the heaters that are on-vehicle devices start driving when the start start time calculated by the start start time calculating means 17 is stored in advance in the memory of the microcomputer 13. Although it has been described that the drive is started prior to the start of the engine 8 when it coincides with the time, the present invention is not limited to this.
The in-vehicle device starts the engine 8 when the start start time calculated by the start start time calculating means 17 coincides with a predetermined time t1 (first predetermined time) stored in advance in the memory of the microcomputer 13A. It may be driven for a predetermined time t1 in advance, driven for a predetermined time t1, and then stopped for a predetermined time t2 (second predetermined time), and thereafter, driving and stopping may be repeated.

FIG. 2 is a block diagram showing an in-vehicle device control system of the in-vehicle device control apparatus according to Embodiment 3 of the present invention.
Here, about the same kind as the said Embodiment 1, "A" is attached | subjected after the same code | symbol, and detailed description is abbreviate | omitted.
In FIG. 2, the in-vehicle device control system includes in-vehicle device intermittent control means 19 instead of the in-vehicle device continuous control means 18 shown in FIG. The in-vehicle device intermittent control means 19 drives the fuel pump 9 for a predetermined time t1 before starting the engine 8 according to the calculated start start time, stops the predetermined time t2 after driving the predetermined time t1, Thereafter, a drive signal for repeatedly driving and stopping is output.
Since other configurations are the same as those in the first embodiment, description thereof is omitted.

Hereinafter, the operation of the in-vehicle device control apparatus according to Embodiment 3 of the present invention will be described with reference to FIG.
Note that the description of the same operation as in the first embodiment is omitted.
Here, the in-vehicle device intermittent control means 19 drives the fuel pump 9 for a predetermined time t1 according to the calculated start time, and stops for a predetermined time t2 after the predetermined time t1 has elapsed. The operation to be performed repeatedly will be described.
First, as shown in the first embodiment, the mobile device search signal transmission unit 14 outputs the mobile device search signal according to the communication result between the mobile device 2 and the in-vehicle communication device 12. At every predetermined time for transmission, the start time for starting the engine of the vehicle 1A by the driver is calculated.

The in-vehicle device intermittent control means 19 sends the engine to the fuel pump 9 when the start start time calculated by the start start time calculation means 17 coincides with a predetermined time t1 stored in advance in the memory of the microcomputer 13A. Prior to the start of 8, a drive signal for starting the drive is output.
Subsequently, the in-vehicle device intermittent control means 19 outputs a drive signal for stopping the drive to the fuel pump 9 when a predetermined time t1 has elapsed from the start of the drive of the fuel pump 9.
Here, when the driver starts the engine while the drive of the fuel pump 9 is stopped, the drive of the fuel pump 9 is started again in the same manner as in normal engine control, which is the same as in normal engine operation. Is performed.

Further, the in-vehicle device intermittent control means 19 detects that the fuel does not start when the predetermined time t2 stored in the memory of the microcomputer 13A elapses without the driver starting the engine after the drive of the fuel pump 9 is stopped. A drive signal for starting driving again is output to the pump 9.
Thereafter, the in-vehicle device intermittent control means 19 repeats the control to drive the fuel pump 9 for a predetermined time t1 and then stop for the predetermined time t2 until the driver starts the engine or the door lock 7 is locked. To implement.
When the door lock 7 is locked, it is determined that the engine 8 is not started, the drive of the fuel pump 9 is stopped, and the vehicle 1A is parked.

Here, the predetermined time t1 indicates the drive time of the fuel pump 9 necessary for the fuel pressure of the fuel supplied to the engine 8, that is, the pressure of the fuel line 11D to reach the predetermined pressure. The predetermined pressure indicates a fuel pressure at which the engine 8 can be started satisfactorily.
Further, during the predetermined time t2, the fuel pressure of the fuel supplied to the engine 8 is lower than the minimum value of the fuel pressure at which the engine 8 can be started satisfactorily, and the fuel pressure at which the engine 8 cannot be started satisfactorily. The time required to reach is shown.
The predetermined times t1 and t2 are times set for each vehicle, for example, according to the environment such as the outside air temperature.

In the above description, the in-vehicle device intermittent control means 19 outputs a drive signal to the fuel pump 9, but the present invention is not limited to this.
The vehicle 1A further includes an airflow sensor, an oxygen sensor, and various heaters (not shown) as in-vehicle devices, and the in-vehicle device intermittent control means 19 has a start start time calculated by the start start time calculation means 17 of the microcomputer 13A. When it coincides with a predetermined time t21 (first predetermined time) stored in advance in the memory, similarly to the fuel pump 9, the air flow sensor, oxygen sensor, and various heaters are driven prior to starting the engine 8. The drive signal which starts is output.

Subsequently, the in-vehicle device intermittent control means 19 drives the air flow sensor, the oxygen sensor, and the various heaters to stop driving when a predetermined time t21 has elapsed from the start of driving the air flow sensor, the oxygen sensor, and the various heaters. Is output.
When the driver starts the engine with the airflow sensor, oxygen sensor, and various heaters stopped, the airflow sensor, oxygen sensor, and various heaters are driven as in normal engine control. Is started again, and the same operation as during normal engine operation is performed.

Further, the in-vehicle device intermittent control means 19 is a predetermined time previously stored in the memory of the microcomputer 13A without the driver starting the engine after the driving of the air flow sensor, oxygen sensor, and various heaters is stopped. When t22 (second predetermined time) elapses, a drive signal for starting driving again is output to the air flow sensor, the oxygen sensor, and various heaters.
Thereafter, the in-vehicle device intermittent control means 19 drives the air flow sensor, oxygen sensor, and various heaters for a predetermined time t21 until the driver starts the engine or the door lock 7 is locked, and then continues for the predetermined time. The control to stop at t22 is repeated.
When the door lock 7 is locked, it is determined that the engine 8 is not started, the driving of the air flow sensor, oxygen sensor, and various heaters is stopped, and the vehicle 1A is parked.

Here, the predetermined time t21 indicates the drive times of the air flow sensor, the oxygen sensor, and the various heaters necessary for the temperature of the air flow sensor, the oxygen sensor, and the various heaters to reach a predetermined temperature, respectively. The predetermined temperature indicates a temperature at which the air flow sensor, the oxygen sensor, and various heaters can operate satisfactorily when the engine 8 is started.
In addition, during the predetermined time t22, the temperature of the airflow sensor, the oxygen sensor, and the various heaters is lower than the minimum value of each temperature at which the airflow sensor, the oxygen sensor, and the various heaters can operate satisfactorily. It shows the time it takes to reach a temperature where it cannot.
Moreover, the predetermined times t21 and t22 are times set individually according to the environment such as the type of the in-vehicle device and the outside temperature.

According to the in-vehicle device control apparatus according to Embodiment 3 of the present invention, the start start time calculating means 17 causes the driver to start the engine of the vehicle 1A according to the communication result between the portable device 2 and the in-vehicle communication device 12. Calculate the start time to start. Further, the in-vehicle device intermittent control means 19 repeatedly performs control for driving the in-vehicle device for a predetermined time t1 (t21) and then stopping for a predetermined time t2 (t22) according to the calculated start time.
That is, when the driver carrying the portable device 2 approaches the vehicle 1A used, the driving of the in-vehicle device is started prior to the start of the engine 8 by the drive signal from the in-vehicle device intermittent control means 19, and the in-vehicle device is driven. When a predetermined time t1 (t21) elapses from the start, driving of the in-vehicle device is stopped for a predetermined time t2 (t22). Further, when the driver starts the engine start, normal driving of the in-vehicle device is performed.
Therefore, with respect to the fuel pump 9, when starting the engine 8, it is possible to reduce the driving energy required to increase the fuel pressure of the fuel supplied to the engine 8 to a fuel pressure that can be started satisfactorily. Further, as in the first embodiment, the fuel pump 9 can be put into a suitable operating state before the engine 8 is started.
Further, with respect to the air flow sensor, the oxygen sensor, and various heaters, when the engine 8 is started, the driving energy required to raise the temperature of the air flow sensor, the oxygen sensor, and the various heaters to a temperature at which the air flow sensor, the oxygen sensor, and the various heaters can operate satisfactorily. be able to. Further, as in the first embodiment, the operation of the sensors and heaters becomes good, so that the control performance of the control system using these sensors and heaters can be made good.

Embodiment 4 FIG.
In the first embodiment, when the start start time calculated by the start start time calculating means 17 matches the drive start time using the drive start time stored in advance in the memory of the microcomputer 13, the in-vehicle device A drive signal for starting driving is output to the fuel pump 9, sensors, and heaters prior to starting the engine 8. However, the present invention is not limited to this.
The drive start time may be set based on the state of the in-vehicle device.

3 is a block diagram showing an in-vehicle device control system of an in-vehicle device control apparatus according to Embodiment 4 of the present invention.
Here, for the same type as in the first embodiment, “B” is appended after the same reference numeral, and detailed description is omitted.
In FIG. 3, an in-vehicle device control unit 5B of the in-vehicle device control system is provided in the fuel line 11D, and a fuel pressure sensor 20 (in-vehicle device state detecting means) that detects the fuel pressure (device state) boosted by the fuel pump 9. In addition.

The in-vehicle device control system includes in-vehicle device continuous control means 18B instead of the in-vehicle device continuous control means 18 shown in FIG. The in-vehicle device continuous control means 18B sets the drive start time based on the fuel pressure detected by the fuel pressure sensor 20, and sets it based on the start start time calculated by the start start time calculation means 17 and the fuel pressure. A drive signal for starting driving is output to the fuel pump 9 prior to starting the engine 8 in accordance with the drive start time.
Since other configurations are the same as those in the first embodiment, description thereof is omitted.

The operation of the in-vehicle device control apparatus according to Embodiment 4 of the present invention will be described below with reference to FIG.
Note that the description of the same operation as in the first embodiment is omitted.
Here, the in-vehicle device continuous control means 18B starts driving the fuel pump 9 according to the start start time calculated by the start start time calculating means 17 and the drive start time set based on the fuel pressure. The operation will be described.
First, as shown in the first embodiment, the mobile device search signal transmission unit 14 outputs the mobile device search signal according to the communication result between the mobile device 2 and the in-vehicle communication device 12. The start time for starting the engine start of the vehicle 1B is calculated by the driver every predetermined time for transmission.

The fuel pressure sensor 20 detects the fuel pressure boosted by the fuel pump 9 every predetermined time when the portable device search signal transmission means 14 transmits the portable device search signal or every time shorter than the predetermined time.
Here, the fuel pressure does not necessarily have the same value depending on the elapsed time from the time when the engine 8 was started and stopped last time to the time when the engine 8 is started this time.

  For example, if the elapsed time from the time when the engine 8 was started and stopped last time to the time when the engine 8 is started this time is long, the fuel pressure has decreased, so in order to start the engine 8 well, Prior to starting the engine 8, the drive time of the fuel pump 9 that increases the fuel pressure needs to be increased. Further, when the elapsed time from the time when the engine 8 was started and stopped last time to the time when the engine 8 is started this time is short, the fuel pressure is relatively high, so the driving time of the fuel pump 9 is short. Good.

Therefore, the in-vehicle device continuous control means 18B sets the drive start time longer when the fuel pressure detected by the fuel pressure sensor 20 is relatively low. The drive start time when the fuel pressure is relatively low may be, for example, the same time as the drive start time stored in advance in the memory of the microcomputer 13 in the first embodiment.
The on-vehicle equipment continuous control means 18B sets the drive start time shorter when the fuel pressure detected by the fuel pressure sensor 20 is relatively high.
Here, the relationship between the fuel pressure and the drive start time may be stored as a map in the memory of the microcomputer 13B.

  Subsequently, the in-vehicle device continuous control unit 18B determines that the fuel pump 9 is in the case where the start start time calculated by the start start time calculating unit 17 coincides with the drive start time set as described above based on the fuel pressure. In contrast, a drive signal for starting driving is output prior to starting the engine 8.

In the above description, the in-vehicle device continuous control means 18B outputs a drive signal to the fuel pump 9, but the present invention is not limited to this.
The vehicle 1B includes an airflow sensor, an oxygen sensor, and various heaters (not shown) as in-vehicle devices, and a plurality of temperature sensors (in-vehicle device state detection means) that detect temperatures (device states) of the airflow sensor, oxygen sensor, and various heaters, respectively. ) And further.

The plurality of temperature sensors respectively detect the temperature of the air flow sensor, the oxygen sensor, and various heaters at every predetermined time when the portable device search signal transmission means 14 transmits the portable device search signal or at a time shorter than the predetermined time. To do.
Here, the temperatures of the air flow sensor, the oxygen sensor, and the various heaters do not necessarily have the same value depending on the elapsed time from the time when the engine 8 was started and stopped last time to the time when the engine 8 is started this time.

For example, when the elapsed time from the time when the engine 8 was started and stopped last time to the time when the engine 8 is started this time is long, the temperatures of the air flow sensor, the oxygen sensor, and various heaters are decreased. In order to improve the operation of the airflow sensor, the oxygen sensor, and the various heaters, it is necessary to lengthen the drive time of the airflow sensor, the oxygen sensor, and the various heaters that are driven before the engine 8 is started.
Further, when the elapsed time from the time when the engine 8 was started and stopped last time to the time when the engine 8 is started this time is short, the temperatures of the air flow sensor, the oxygen sensor, and various heaters are relatively high. The driving time of the air flow sensor, oxygen sensor, and various heaters may be short.

Therefore, the in-vehicle equipment continuous control means 18B sets the drive start time longer when the temperatures of the airflow sensor, the oxygen sensor, and the various heaters detected by the plurality of temperature sensors are relatively low. The drive start time when the temperature of each of the air flow sensor, the oxygen sensor, and the various heaters is relatively low is, for example, the air flow sensor, the oxygen sensor, and the various types that are stored in advance in the memory of the microcomputer 13 in the first embodiment. The time may be about the same as the drive start time of each heater.
The on-vehicle equipment continuous control means 18B sets the drive start time shorter when the temperatures of the airflow sensor, the oxygen sensor, and the various heaters detected by the plurality of temperature sensors are relatively high.

  Subsequently, the in-vehicle device continuous control unit 18B has the drive in which the start start time calculated by the start start time calculating unit 17 is set as described above based on the temperatures of the air flow sensor, the oxygen sensor, and the various heaters. When it coincides with the start time, a driving signal for starting driving is output to the air flow sensor, the oxygen sensor, and various heaters prior to starting the engine 8.

According to the in-vehicle device control apparatus according to Embodiment 4 of the present invention, the start start time calculating means 17 causes the driver to start the engine of the vehicle 1B according to the communication result between the portable device 2 and the in-vehicle communication device 12. Calculate the start time to start. The in-vehicle device continuous control means 18B starts driving the in-vehicle device according to the calculated start start time and the drive start time set based on the outputs from the fuel pressure sensor 20 and the plurality of temperature sensors. To do.
That is, when the driver carrying the portable device 2 approaches the vehicle 1B used, the drive of the vehicle-mounted device is started prior to the start of the engine 8 by the drive signal from the vehicle-mounted device continuous control means 18B. From the start, after the drive start time set as described above based on the state of the in-vehicle device has elapsed, the driver starts the engine.
Therefore, when the engine 8 is started, the driving time of the in-vehicle device becomes excessive, the driving energy of the in-vehicle device is not wasted, and the driving energy of the in-vehicle device is set to an optimum consumption amount that is not excessive or insufficient. it can.
In addition, the drive time of the in-vehicle device is shortened, the fuel pressure of the fuel supplied to the engine 8 is insufficient, the operation of the sensors becomes unstable, the temperature rise of the heaters is insufficient, There is no inconvenience that the performance of the in-vehicle device is not sufficiently exhibited, and the in-vehicle device can be brought into a suitable operating state with optimum energy consumption before the engine 8 is started.
Further, the fuel pressure is optimized with the optimum energy consumption, the startability of the engine 8 is improved, and the operations of the sensors and heaters are improved, whereby a control system using these sensors and heaters is provided. The control performance can be improved.

Embodiment 5. FIG.
In Embodiment 4 described above, the fuel pump 9, which is an on-vehicle device, sensors, and heaters, output from the fuel pressure sensor 20 and the plurality of temperature sensors is the start start time calculated by the start start time calculating means 17. Although it has been described that the drive is started prior to the start of the engine 8 when it coincides with the drive start time set based on the above, it is not limited to this.
In the in-vehicle device, the start start time calculated by the start start time calculating means 17 coincides with a predetermined time t3 (first predetermined time) set based on outputs from the fuel pressure sensor 20 and the plurality of temperature sensors. In this case, the engine 8 is driven for a predetermined time t3 prior to the start of the engine 8, driven for a predetermined time t3, and then stopped for a predetermined time t4 (second predetermined time), and thereafter the driving and stopping are repeated. May be implemented.

FIG. 4 is a block diagram showing an in-vehicle device control system of the in-vehicle device control apparatus according to Embodiment 5 of the present invention.
Here, for the same type as in the fourth embodiment, “C” is appended after the same reference numeral, and the detailed description is omitted.
In FIG. 4, the in-vehicle device control system includes in-vehicle device intermittent control means 19C instead of the in-vehicle device continuous control means 18B shown in FIG. The in-vehicle device intermittent control means 19C sets a predetermined time t3 based on the fuel pressure detected by the fuel pressure sensor 20, and responds to the start start time calculated by the start start time calculation means 17 and the predetermined time t3. Then, the fuel pump 9 is driven for a predetermined time t3 prior to the start of the engine 8, and after the predetermined time t3 is driven, the fuel pump 9 is stopped for a predetermined time t4.
Other configurations are the same as those in the fourth embodiment, and thus the description thereof is omitted.

Hereinafter, the operation of the in-vehicle device control apparatus according to Embodiment 5 of the present invention will be described with reference to FIG.
Note that description of operations similar to those of the fourth embodiment is omitted.
Here, the in-vehicle device intermittent control means 19C sets the fuel pump 9 to a predetermined time t3 in accordance with the start time calculated by the start time calculation means 17 and the predetermined time t3 set based on the fuel pressure. A description will be given of an operation of repeatedly driving and repeatedly performing control of stopping for a predetermined time t4 after the predetermined time t3 has elapsed.
First, as shown in the first embodiment, the mobile device search signal transmission unit 14 outputs the mobile device search signal according to the communication result between the mobile device 2 and the in-vehicle communication device 12. At every predetermined time for transmission, a start start time for the driver to start the engine of the vehicle 1C is calculated.

The fuel pressure sensor 20 detects the fuel pressure boosted by the fuel pump 9 every predetermined time when the portable device search signal transmission means 14 transmits the portable device search signal or every time shorter than the predetermined time.
When the fuel pressure detected by the fuel pressure sensor 20 is relatively low, the in-vehicle device intermittent control means 19C sets the predetermined time t3 longer. The predetermined time t3 when the fuel pressure is relatively low may be, for example, the same time as the drive start time stored in advance in the memory of the microcomputer 13 in the first embodiment.
Further, the in-vehicle device intermittent control means 19C sets the predetermined time t3 to be shorter when the fuel pressure detected by the fuel pressure sensor 20 is relatively high.
Here, the relationship between the fuel pressure and the predetermined time t3 may be stored as a map in the memory of the microcomputer 13C.

Next, the in-vehicle device intermittent control means 19C drives the fuel pump 9 prior to the start of the engine 8 when the start start time calculated by the start start time calculation means 17 coincides with the predetermined time t3. The drive signal which starts is output.
Subsequently, the in-vehicle device intermittent control means 19 </ b> C outputs a drive signal for stopping the driving to the fuel pump 9 when a predetermined time t <b> 3 has elapsed from the start of driving of the fuel pump 9.
Here, when the driver starts the engine while the drive of the fuel pump 9 is stopped, the drive of the fuel pump 9 is started again in the same manner as in normal engine control, which is the same as in normal engine operation. Is performed.

Further, the on-vehicle equipment intermittent control means 19 </ b> C is configured such that when the predetermined time t <b> 4 previously stored in the memory of the microcomputer 13 </ b> C elapses without the driver starting the engine after the drive of the fuel pump 9 is stopped, A drive signal for starting driving again is output to the pump 9.
Thereafter, the in-vehicle device intermittent control means 19C repeats the control of driving the fuel pump 9 for a predetermined time t3 and then stopping the predetermined time t4 until the driver starts the engine or the door lock 7 is locked. To implement.
When the door lock 7 is locked, it is determined that the engine 8 is not started, the drive of the fuel pump 9 is stopped, and the vehicle 1C is parked.

Here, the predetermined time t3 indicates the drive time of the fuel pump 9 necessary for the fuel pressure of the fuel supplied to the engine 8, that is, the pressure of the fuel line 11D to reach the predetermined pressure. The predetermined pressure indicates a fuel pressure at which the engine 8 can be started satisfactorily.
Further, at the predetermined time t4, the fuel pressure of the fuel supplied to the engine 8 is lower than the minimum value of the fuel pressure at which the engine 8 can be started satisfactorily, and the fuel pressure at which the engine 8 cannot be started satisfactorily. The time required to reach is shown.
The predetermined times t3 and t4 are times set for each vehicle, for example, according to the environment such as the outside air temperature.

In the above description, the in-vehicle device intermittent control means 19C outputs a drive signal to the fuel pump 9, but the present invention is not limited to this.
The vehicle 1C includes an air flow sensor, an oxygen sensor, and various heaters (not shown) as in-vehicle devices, and a plurality of temperature sensors (in-vehicle device state detection means) that detect temperatures (device states) of the air flow sensor, the oxygen sensor, and various heaters, respectively. ) And further.
The plurality of temperature sensors respectively detect the temperature of the air flow sensor, the oxygen sensor, and various heaters at every predetermined time when the portable device search signal transmission means 14 transmits the portable device search signal or at a time shorter than the predetermined time. To do.

The in-vehicle device intermittent control means 19C increases the predetermined time t41 (first predetermined time) when the temperatures of the air flow sensor, the oxygen sensor, and the various heaters detected by the plurality of temperature sensors are relatively low. Set. The predetermined time t41 when the temperature of each of the air flow sensor, the oxygen sensor, and the various heaters is relatively low is, for example, the air flow sensor, the oxygen sensor, and the various types that are stored in advance in the memory of the microcomputer 13 in the first embodiment. The time may be about the same as the drive start time of each heater.
Further, the in-vehicle device intermittent control means 19C sets the predetermined time t41 to be shorter when the temperatures of the air flow sensor, the oxygen sensor, and the various heaters detected by the plurality of temperature sensors are relatively high.

Next, when the start start time calculated by the start start time calculating means 17 coincides with the predetermined time t41, the in-vehicle equipment intermittent control means 19C is similar to the fuel pump 9 and includes an air flow sensor, an oxygen sensor, and various types. Prior to starting the engine 8, a drive signal for starting driving is output to the heater.
Subsequently, the on-vehicle equipment intermittent control means 19C drives the air flow sensor, the oxygen sensor, and the various heaters to stop driving when a predetermined time t41 has elapsed from the start of driving the air flow sensor, the oxygen sensor, and the various heaters. Is output.
When the driver starts the engine with the airflow sensor, oxygen sensor, and various heaters stopped, the airflow sensor, oxygen sensor, and various heaters are driven as in normal engine control. Is started again, and the same operation as during normal engine operation is performed.

Further, the in-vehicle device intermittent control means 19 </ b> C has a predetermined time stored in the memory of the microcomputer 13 </ b> C in advance without the driver starting the engine after the driving of the air flow sensor, the oxygen sensor, and the various heaters is stopped. When t42 (second predetermined time) elapses, a drive signal for starting driving again is output to the air flow sensor, the oxygen sensor, and various heaters.
Thereafter, the in-vehicle device intermittent control means 19C drives the air flow sensor, the oxygen sensor, and various heaters for a predetermined time t41 until the driver starts the engine or the door lock 7 is locked, and then continues for the predetermined time. The control for stopping t42 is repeated.
When the door lock 7 is locked, it is determined that the engine 8 is not started, the driving of the air flow sensor, oxygen sensor, and various heaters is stopped, and the vehicle 1C is parked.

Here, the predetermined time t41 indicates the drive times of the air flow sensor, the oxygen sensor, and the various heaters that are necessary for the temperatures of the air flow sensor, the oxygen sensor, and the various heaters to reach the predetermined temperatures, respectively. The predetermined temperature indicates a temperature at which the air flow sensor, the oxygen sensor, and various heaters can operate satisfactorily when the engine 8 is started.
In addition, at the predetermined time t42, the temperature of the air flow sensor, the oxygen sensor, and the various heaters is lower than the minimum value of each temperature at which the air flow sensor, the oxygen sensor, and the various heaters can operate satisfactorily. It shows the time it takes to reach a temperature where it cannot.
Moreover, the predetermined times t41 and t42 are times set individually according to the environment such as the type of the in-vehicle device and the outside temperature.

According to the in-vehicle device control apparatus according to Embodiment 5 of the present invention, the start start time calculating means 17 causes the driver to start the engine of the vehicle 1C according to the communication result between the portable device 2 and the in-vehicle communication device 12. Calculate the start time to start. The in-vehicle device intermittent control means 19C sets the in-vehicle device for a predetermined time t3 according to the calculated start start time and the drive start time set based on the outputs from the fuel pressure sensor 20 and the plurality of temperature sensors. (T41) The control of driving and then stopping for a predetermined time t4 (t42) is repeatedly performed.
That is, when the driver carrying the portable device 2 approaches the vehicle 1C to be used, the driving of the in-vehicle device is started prior to the start of the engine 8 by the drive signal from the in-vehicle device intermittent control means 19C. When a predetermined time t3 (t41) elapses from the start, driving of the in-vehicle device is stopped for a predetermined time t4 (t42). Further, when the driver starts the engine start, normal driving of the in-vehicle device is performed.
Therefore, with respect to the fuel pump 9, when starting the engine 8, it is possible to further reduce the driving energy required for increasing the fuel pressure of the fuel supplied to the engine 8 to a fuel pressure that can be started satisfactorily. Further, as in the first embodiment, the fuel pump 9 can be put into a suitable operating state before the engine 8 is started.
In addition, with regard to the air flow sensor, oxygen sensor, and various heaters, when the engine 8 is started, the driving energy necessary for raising the temperature of the air flow sensor, oxygen sensor, and various heaters to a temperature at which the air flow sensor, oxygen heater, and the like can be operated is further reduced. can do. Further, as in the first embodiment, the operation of the sensors and heaters becomes good, so that the control performance of the control system using these sensors and heaters can be made good.

It is a block diagram which shows the vehicle equipment control system of the vehicle equipment control apparatus which concerns on Embodiment 1 and 2 of this invention. It is a block diagram which shows the vehicle equipment control system of the vehicle equipment control apparatus which concerns on Embodiment 3 of this invention. It is a block diagram which shows the vehicle equipment control system of the vehicle equipment control apparatus which concerns on Embodiment 4 of this invention. It is a block diagram which shows the vehicle equipment control system of the vehicle equipment control apparatus which concerns on Embodiment 5 of this invention. It is a block diagram which shows the conventional electronic control apparatus for motor vehicles. It is a block diagram which shows the conventional fuel pump drive control apparatus. It is a block diagram which shows the conventional fuel supply apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1, 1A-1C Vehicle, 2 Portable machine, 8 Engine, 9 Fuel pump (vehicle equipment), 12 Car communication device (communication means), 17 Start start time calculation means, 18, 18B Vehicle equipment continuous control means, 19, 19C In-vehicle device intermittent control means, 20 fuel pressure sensor (in-vehicle device state detection means).

Claims (4)

A portable device carried by the vehicle user;
A communication means provided in the vehicle for communicating with the portable device;
A start start time calculating means for calculating a start start time for the user to start the engine of the vehicle according to a communication result by communication between the portable device and the communication means provided in the vehicle;
A vehicle-mounted device control device comprising: vehicle-mounted device continuous control means for starting driving of a predetermined vehicle-mounted device of the vehicle according to the start start time. A portable device carried by the vehicle user;
A communication means provided in the vehicle for communicating with the portable device;
A start start time calculating means for calculating a start start time for the user to start the engine of the vehicle according to a communication result by communication between the portable device and the communication means provided in the vehicle;
In accordance with the start-up time, a predetermined on-vehicle device of the vehicle is driven for a first predetermined time, and the control is stopped for a second predetermined time after the first predetermined time has elapsed. An in-vehicle device control device comprising: an in-vehicle device intermittent control means that performs the operation. It further comprises an in-vehicle device state detecting means for detecting the state of the in-vehicle device as a device state,
The in-vehicle device continuous control means starts driving the in-vehicle device in accordance with the start start time output from the start start time calculating means and the device state output from the in-vehicle device state detection means. The in-vehicle device control device according to claim 1. It further comprises an in-vehicle device state detecting means for detecting the state of the in-vehicle device as a device state,
The in-vehicle device intermittent control means determines a predetermined in-vehicle device of the vehicle according to the start start time output from the start start time calculating means and the device state output from the in-vehicle device state detection means. The vehicle-mounted device according to claim 2, wherein the control is repeated for driving for a first predetermined time and stopping for a second predetermined time after the first predetermined time has elapsed. Control device.

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