JP4742979B2 - Keyless entry system - Google Patents

Description

  The present invention relates to a keyless entry system, and more particularly to a keyless entry system that recognizes the position of a portable device by transmitting a request signal from a vehicle exterior antenna and a vehicle interior antenna when a switch is operated.

  2. Description of the Related Art In recent years, a keyless entry system that has become widespread controls the locking / unlocking of a vehicle door and the ignition on of an engine when a portable device responds to a request from an in-vehicle device.

  In Patent Document 1, when the user operates the door handle switch, the return signal of the portable device is sequentially checked against the request signal in the vehicle interior and the vehicle interior. Describes that it is determined that the door is locked when the portable device is taken out of the passenger compartment by the user's intention, and the door is locked.

  Patent Document 2 describes a smart entry system that transmits from an outdoor detection antenna when a door is opened, and issues a warning when there is no response, judging that it has been left behind.

  Patent Document 3 describes a keyless entry system that detects the presence of a person in the driver's seat and that can start the engine only when authenticated in the room.

Patent Document 4 describes a method for determining the position of a portable device from a response to a request signal from an antenna that overlaps a part of the communicable area.
JP 2000-145228 A JP 2001-207709 A JP 2004-74850 A JP 2005-76329 A

  In the technique described in Patent Document 1, since the request signal from the vehicle interior leaks outside the vehicle interior, if the mobile device exists in an area where the request signal from the vehicle interior leaks outside the vehicle interior, the mobile device is installed in the vehicle interior. There is a risk of misrecognizing that it exists. In this case, there is a problem that the door is not locked in order to prevent the portable device from being left in the vehicle interior, and that the engine can be started.

  The present invention has been made in view of the above points, and an object thereof is to provide a keyless entry system capable of improving the position recognition accuracy of a portable device.

The keyless entry system of the present invention transmits a request signal from the vehicle exterior antenna and vehicle interior antenna when the switch is operated, and collates the return signal code returned from the portable device with the request signal against a predetermined code. In the keyless entry system for recognizing the position of the portable device,
When matching of return signals with respect to request signals of both the antenna for vehicle exterior and the antenna for vehicle interior coincides, the signal strength of at least one of the antenna for vehicle exterior and the antenna for vehicle interior is reduced. wherein transmitting the request signal again, it has rows matching return signal Te,
The vehicle exterior antenna is provided for each door handle together with a switch,
The vehicle exterior antenna that reduces the signal strength is a vehicle exterior antenna corresponding to the operated switch,
The vehicle interior antenna that reduces the signal strength is the vehicle interior antenna that is closest to the operated switch, so that the position recognition accuracy of the portable device can be improved.

In the keyless entry system,
When the verification of the return signal with respect to the request signal of both the antenna for vehicle exterior and the antenna for vehicle interior coincides, the signal strength of both the antenna for vehicle exterior and the antenna for vehicle interior is lowered to The signal can be sent again and the return signal can be verified.

In the keyless entry system,
The switch may be a trigger switch provided on the door handle.

In the keyless entry system,
The switch may be a push button switch.

  According to the present invention, the position recognition accuracy of a portable device can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<Configuration of in-vehicle device and portable device>
FIG. 1 shows a block diagram of an embodiment of an in-vehicle device. In the figure, the vehicle-mounted device 10 has a first transmission antenna 11 and a second transmission antenna 12. The first transmission antenna 11 is provided, for example, on a door handle of a vehicle (four-wheeled vehicle). On the other hand, the second transmitting antenna 12 is provided in the center console or on the floor surface of the vehicle interior. The first transmission antenna 11 is connected to the first transmission unit 14, and the second transmission antenna 12 is connected to the second transmission unit 16. The first transmitter 14 and the second transmitter 16 are connected to an ECU (electronic control unit) 20.

  The ECU 20 supplies a request code to each of the first transmission unit 14 and the second transmission unit 16, and a request signal having a frequency, for example, 134 kHz, obtained by modulating the request code is transmitted from the first transmission antenna 11 and the second transmission antenna 12 to the portable device 60. Sent to. Transmission of the request signal from the first transmission antenna 11 is referred to as a request outside the vehicle interior, and transmission of the request signal from the second transmission antenna 12 is referred to as a vehicle interior request. The vehicle is provided with a receiving antenna 22, and a signal having a frequency of, for example, 300 MHz from the portable device 60 received by the receiving antenna 22 is demodulated by the receiving unit 24 and supplied to the ECU 20.

  A memory 26 is connected to the ECU 20, and a plurality of different codes such as a first door lock code, a second engine start code, and a transponder ID code are stored in the memory 26. The memory 26 is a nonvolatile memory such as an EEPROM, and the stored contents are retained even when the power is turned off.

  The push button switch 28 supplies the operation detection signal to the ECU 20. The trigger switch 30 is provided in the door handle, detects the user's pushing operation, and supplies the detection signal to the ECU 20.

  In addition, a steering lock unit 40, an immobilizer unit 42, and a door lock unit 44 are connected to the ECU 20. The steering lock unit 40 is a mechanism for mechanically prohibiting the steering operation. The immobilizer unit 42 is a mechanism for prohibiting fuel supply to the engine 50 and ignition operation. The door lock unit 44 is a mechanism for locking / unlocking all doors. Further, the ECU 20 is connected to an engine control unit 48, and the engine control unit 48 can control the start of the engine 50 using a cell motor and can also control the driving stop of the engine 50. In addition, the ECU 20 issues an alarm by the alarm device 52.

  FIG. 2 shows a block diagram of an embodiment of a portable device. In the figure, the portable device 60 has a transmission antenna 62 and a reception antenna 64. These antennas 62 and 64 are connected to a transmission / reception circuit 66, and the transmission / reception circuit 66 is connected to an ECU 68.

  A request signal having a frequency of, for example, 134 kHz from the vehicle-mounted device 10 received by the receiving antenna 64 is demodulated by the transmission / reception circuit 66 and supplied to the ECU 68. Further, the ECU 68 supplies the first and second codes read from the memory 70 to the transmission / reception circuit 66, and the first and second codes are modulated by the transmission / reception circuit 66 and are transmitted from the transmission antenna 62 at a frequency of, for example, 300 MHz. Sent to.

<First Embodiment>
FIG. 3 shows a flowchart of the first embodiment of the process executed by the ECU 20. In the figure, it is determined whether or not the trigger switch 30 provided on the door handle has been pushed in step S11. If the trigger switch 30 has been pushed, the process proceeds to step S12.

  In step S12, a request signal is transmitted from the first transmitting antenna 11 to make a request outside the vehicle interior, and code verification of a return signal returned from the portable device 60 by the reception antenna 22, that is, vehicle exterior verification is performed. Further, in step S13, a request signal is transmitted from the second transmitting antenna 12 to make a vehicle interior request, and code verification of the return signal returned from the portable device 60 by the receiving antenna 22, that is, vehicle interior verification is performed.

  In FIG. 4, an out-of-cabinable collation area in which the portable device 60 can receive an out-of-vehicle request from the first transmitting antenna 11 in the vehicle 80 at this time is indicated by a broken line AO <b> 1. Is indicated by an alternate long and short dash line AI1. That is, a part of the vehicle interior verification possible area enters the vehicle interior, and a part of the vehicle interior verification possible area leaks out of the vehicle interior.

  Next, in step S14, a vehicle interior / exterior determination is made as to whether the results of vehicle exterior verification and vehicle interior verification are OK or NG. If the vehicle exterior verification is NG and the vehicle interior verification is OK, it is assumed that the portable device 60 has been left behind in the vehicle interior, an alarm is issued from the alarm device 52 in step S15, and the process returns to step S11. When the vehicle exterior verification is NG and the vehicle interior verification is NG, the process returns to step S11.

  On the other hand, if the vehicle interior verification is OK and the vehicle interior verification is NG, the portable device 60 is outside the vehicle interior, so that all doors are locked by the door lock unit 44 in step S21, and this process is terminated.

  In addition, when the vehicle exterior verification is OK and the vehicle interior verification is OK, since it is not known whether the portable device 60 is outside the vehicle compartment or in the vehicle interior, the first transmission unit 14 and the second transmission unit in step S16. Each of the 16 transmission powers is reduced by a predetermined amount to reduce the signal strength of the request signal. The decrease in the transmission power may decrease the voltage or the current.

  As a result, the vehicle interior verification possible area in which the portable device 60 can receive the vehicle exterior request from the first transmission antenna 11 in the vehicle 80 is reduced as indicated by the broken line AO2 in FIG. The vehicle interior verification area in which the portable device 60 can receive the vehicle interior request is reduced as indicated by a one-dot chain line AI2.

  FIG. 5 shows an enlarged view of FIG. If it is assumed in step S16 that the vehicle interior verification possible area is reduced as indicated by the one-dot chain line AI2 while the vehicle exterior verification possible area remains the broken line AO1, the area indicated by the right-down hatching in FIG. The collation becomes NG and the door can be locked, and there is a risk that the portable device 60 may be left behind in the vehicle interior. There is no risk of leaving the portable device 60 in the passenger compartment.

  In addition, the area | region shown by the left-downward hatching of FIG.4 and FIG.5 is a part which prevented the misdetection by reducing the vehicle exterior collation possible area from the broken line AO1 to the broken line AO2.

  Thereafter, in step S17, a request signal is transmitted from the first transmission antenna 11 to make a request outside the vehicle interior, and code verification of a return signal returned from the portable device 60 by the reception antenna 22, that is, vehicle exterior verification is performed. Further, in step S18, a request signal is transmitted from the second transmission antenna 12 to make a vehicle interior request, and code verification of a return signal returned from the portable device 60 by the reception antenna 22, that is, vehicle interior verification is performed.

  Next, in step S19, a vehicle interior / exterior determination is made as to whether the results of the vehicle interior verification and vehicle interior verification are OK or NG. If the vehicle exterior verification is OK and the vehicle interior verification is OK, it is considered that the portable device 60 has been left behind in the vehicle interior, an alarm is issued from the alarm device 52 in step S20, and the process returns to step S11.

  On the other hand, if the vehicle interior verification is OK and the vehicle interior verification is NG, the portable device 60 is outside the vehicle interior, so that all doors are locked by the door lock unit 44 in step S21, and this process is terminated.

  If the vehicle interior verification is OK and the vehicle interior verification is OK in step S19, the process proceeds to step S16 instead of proceeding to step S19, and the vehicle interior verification area and the vehicle interior verification area are further reduced. It is good also as a structure.

  As described above, when the vehicle exterior verification is OK and the vehicle interior verification is OK, the position recognition accuracy of the portable device can be improved by reducing the vehicle exterior verification possible area and the vehicle interior verification possible area.

<Arrangement of first transmission antenna and second transmission antenna>
FIG. 6 shows an arrangement of a plurality of first transmission antennas and second transmission antennas in the vehicle. In the figure, the first transmission antenna 11a is provided on the door handle of the right front door (driver's seat door) of the vehicle 80, the first transmission antenna 11b is provided on the door handle of the left front door, and the door of the right rear door. The handle is provided with a first transmission antenna 11c, and the door handle of the left rear door is provided with a first transmission antenna 11d. Trigger switches (30a to 30d) are provided adjacent to the first transmission antennas 11a to 11d, respectively.

  A second transmission antenna 12a is provided in the center console and on the floor surface of the vehicle 80, and a second transmission antenna 12b is provided on the lower floor surface of the rear seat. The first transmission antennas 11a and 11b arranged close to each other correspond to the second transmission antenna 12a, and the first transmission antennas 11c and 11d arranged close to each other correspond to the second transmission antenna 12b.

  In this case, for example, when the trigger switch 30c provided alongside the first transmission antenna 11c of the door handle of the right rear door is pushed, the processing shown in FIG. 3 is performed according to the first transmission antenna corresponding to the operated switch. Only the second transmitting antenna 12b closest to the switch operated as 11c is executed. That is, the transmission power of the first transmission antenna 11c and the second transmission antenna 12b is reduced in step S16. The transmission power of the other first transmission antennas 11a, 11b, 11d and the second transmission antenna 12a is not changed. This simplifies control. Moreover, it is possible to reduce power consumption by configuring the other first transmission antennas 11a, 11b, 11d, and second transmission antenna 12a that do not change the transmission power so as not to perform re-collation in steps S17 and S18.

Second Embodiment
FIG. 7 shows a flowchart of a second embodiment of the process executed by the ECU 20. In the figure, it is determined whether or not the push button switch 28 provided in the vicinity of the console panel is pushed in step S31. If the push button switch 28 is pushed, the process proceeds to step S32.

  In step S32, a request signal is transmitted from the first transmission antenna 11 to make a request outside the vehicle interior, and code verification of a return signal returned from the portable device 60 by the reception antenna 22, that is, verification outside the vehicle interior is performed. Further, in step S33, a request signal is transmitted from the second transmitting antenna 12 to make a vehicle interior request, and code verification of a return signal returned from the portable device 60 by the receiving antenna 22, that is, vehicle interior verification is performed.

  Next, in step S34, a vehicle interior / exterior determination is made as to whether the results of the vehicle interior verification and vehicle interior verification are OK or NG. When the vehicle exterior verification is OK and the vehicle interior verification is NG, in order to notify the user that the portable device 60 does not exist in the vehicle interior, an alarm is issued from the alarm device 52 in step S35, and the process returns to step S31. If the vehicle exterior verification is NG and the vehicle interior verification is NG, the process returns to step S31.

  On the other hand, if the vehicle exterior verification is NG and the vehicle interior verification is OK, the portable device 60 is in the vehicle interior, and therefore the engine control unit 48 uses the cell motor to start the engine 50 in step S41. Exit.

  Further, when the vehicle exterior verification is OK and the vehicle interior verification is OK, since it is not known whether the portable device 60 is outside the vehicle compartment or in the vehicle interior, the first transmission unit 14 and the second transmission unit in step S36. Each of the 16 transmission powers is reduced by a predetermined amount to reduce the signal strength of the request signal.

  Thereafter, in step S37, a request signal is transmitted from the first transmitting antenna 11 to make a request outside the vehicle interior, and code verification of a return signal returned from the portable device 60 by the reception antenna 22, that is, vehicle exterior verification is performed. Further, in step S38, a request signal is transmitted from the second transmitting antenna 12 to make a vehicle interior request, and code verification of the return signal returned from the portable device 60 by the receiving antenna 22, that is, vehicle interior verification is performed.

  Next, in step S39, a vehicle interior / exterior determination is made as to whether the results of vehicle exterior verification and vehicle interior verification are OK or NG. When the vehicle exterior verification is OK and the vehicle interior verification is OK, the portable device 60 is regarded as not existing in the vehicle interior, and the alarm device 52 is used in step S40 to notify the user that the portable device 60 is not present in the vehicle interior. An alarm is issued and the process returns to step S31.

  On the other hand, if the vehicle exterior verification is NG and the vehicle interior verification is OK, the portable device 60 is in the vehicle interior, and therefore the engine control unit 48 uses the cell motor to start the engine 50 in step S41. Exit.

  Note that if the vehicle interior verification is OK and the vehicle interior verification is OK in step S39, the process proceeds to step S36 instead of proceeding to step S39, and the vehicle interior verification area and the vehicle interior verification area are further reduced. It is good also as a structure.

  As described above, when the vehicle exterior verification is OK and the vehicle interior verification is OK, the position recognition accuracy of the portable device can be improved by reducing the vehicle exterior verification possible area and the vehicle interior verification possible area.

  Incidentally, in the case of the antenna arrangement shown in FIG. 6, in response to the push operation of the push button switch 28, in step S36 in FIG. 7, the first transmission antenna 11a and the second transmission antenna 12a closest to the operated switch are operated. Only reduce the transmission power. The transmission power of the other first transmission antennas 11b to 11d and the second transmission antenna 12b is not changed. This simplifies control. Further, the power consumption can be reduced by configuring the first transmission antennas 11b to 11d and the second transmission antenna 12b that do not change the transmission power so as not to perform re-collation in steps S37 and S38.

  The trigger switch 30 may be a touch sensor.

  The first transmission antenna 11 corresponds to the vehicle exterior antenna described in the claims, and the second transmission antenna 12 corresponds to the vehicle interior antenna.

It is a block diagram of one embodiment of an in-vehicle device. It is a block diagram of one embodiment of a portable machine. It is a flowchart of 1st Embodiment of the process which ECU20 performs. It is a figure which shows the vehicle interior verification possible area and the vehicle interior verification possible area. FIG. 5 is an enlarged view of FIG. 4. It is a figure which shows arrangement | positioning of several 1st transmission antenna and 2nd transmission antenna. It is a flowchart of 2nd Embodiment of the process which ECU20 performs.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Onboard equipment 11 1st transmission antenna 12 2nd transmission antenna 14 1st transmission part 16 2nd transmission part 20 ECU
DESCRIPTION OF SYMBOLS 22 Reception antenna 28 Push button switch 30 Trigger switch 44 Door lock part 48 Engine control part 60 Portable machine

Claims (4)

When the switch is operated, a request signal is transmitted from the vehicle exterior antenna and the vehicle interior antenna, and the code of the return signal returned from the portable device in response to the request signal is compared with a predetermined code to determine the position of the portable device. In the keyless entry system to recognize
When matching of return signals with respect to request signals of both the antenna for vehicle exterior and the antenna for vehicle interior coincides, the signal strength of at least one of the antenna for vehicle exterior and the antenna for vehicle interior is reduced. wherein transmitting the request signal again, it has rows matching return signal Te,
The vehicle exterior antenna is provided for each door handle together with a switch,
The vehicle exterior antenna that reduces the signal strength is a vehicle exterior antenna corresponding to the operated switch,
The keyless entry system, wherein the vehicle interior antenna for reducing the signal strength is a vehicle interior antenna closest to the operated switch . The keyless entry system according to claim 1,
When the verification of the return signal with respect to the request signal of both the antenna for vehicle exterior and the antenna for vehicle interior coincides, the signal strength of both the antenna for vehicle exterior and the antenna for vehicle interior is lowered to A keyless entry system characterized by transmitting a signal again and collating a return signal. The keyless entry system according to claim 1 or 2 ,
The keyless entry system, wherein the switch is a trigger switch provided on a door handle. The keyless entry system according to claim 1 or 2 ,
The keyless entry system, wherein the switch is a push button switch.

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