JP6351425B2 - Keyless entry device and control method thereof - Google Patents

Description

  The present invention relates to a keyless entry device that locks and unlocks a vehicle door by performing wireless communication between a vehicle-side device and a portable device, and a control method thereof.

In recent years, as a keyless entry device, when a driver with a portable device presses a request switch on the vehicle, communication is automatically performed between the vehicle side device and the portable device, and the key is inserted into the key hole of the door. The one that automatically unlocks the locked door of the vehicle without operation is becoming widespread, and the keyless entry device starts the engine of the vehicle from a position away from the vehicle, etc. Also used for.
In such a keyless entry device, an LF (low frequency) request signal with a limited reach is output from the vehicle side device on the assumption that the driver is near the vehicle for unlocking the door. On the other hand, an RF (high frequency) signal is output from the portable device in order to enable a door lock operation from a remote distance. Therefore, an RF is also used as an answer signal as a response to the request signal. .

By the way, in the case of automatic unlocking of the door of the vehicle, it is necessary for the driver carrying the portable device to approach the vehicle, but the driver is separated from the vehicle by a so-called relay attack using a repeater by a malicious third party. There is a possibility that the door can be unlocked even in the position.
In other words, by relaying the request signal from the vehicle side device by the repeater, the request signal from the vehicle side device can be received even if the portable device is located away from the vehicle, and the answer signal is sent in response to this. Output. If the vehicle side device receives this answer signal and can authenticate that it is from a portable device corresponding to the host vehicle, the vehicle side device will unlock the door to a third party who is not the owner of the vehicle.

As a countermeasure, for example, Japanese Patent Application Laid-Open No. 2010-185186 includes an intensity measurement signal whose output intensity changes midway in the request signal from the vehicle-side device, and the portable device uses a relay attack when the reception intensity does not change. A technique for judging and not returning an answer signal is disclosed.
Since a repeater that does not detect a change in output intensity relays the request signal as a signal having a constant intensity, the portable device cannot detect a change in reception intensity and does not return an answer signal. As a result, the vehicle-side device does not unlock the door, thereby preventing an illegal act by a third party.

JP 2010-185186 A

  However, in Japanese Patent Application Laid-Open No. 2010-185186, the mechanism for changing the radio wave output from the antenna of the vehicle-side device causes an increase in manufacturing cost. Even in the vicinity, there is a possibility that reception may be impossible due to a slight position change of the portable device.

  Accordingly, in view of the above-described conventional problems, the present invention eliminates the need for a mechanism for changing the radio wave output from the antenna of the vehicle-side device and prevents a relay attack while preventing an increase in cost, and a keyless entry device and An object is to provide a control method thereof.

Therefore, the present invention comprises a vehicle-side device that outputs a request signal from an output antenna based on an operation of a request switch installed in the vehicle, and a portable device that returns an answer signal in response to the request signal. In a keyless entry device that authenticates that the vehicle side device is compatible and drives the door lock,
The vehicle side device arranges a plurality of output antennas at different positions of the vehicle body, changes the output order of the plurality of output antennas for each operation of the request switch,
The portable device includes the reception intensity information of the request signal in the answer signal,
In addition to authentication, the vehicle side device further drives the door lock after confirming that the received intensity information corresponds to the reference data based on the above output order.

According to the present invention, even if the output strength of the output antenna is fixed, the reception strength differs for each output antenna depending on the position of the portable device. Therefore, it is not necessary to provide a circuit for changing the output of the request signal, and the configuration is complicated and the cost is increased. Can be avoided, and there is no fear of reception failure due to excessive output reduction.
Then, it can be confirmed that the portable device is located in the vicinity of the vehicle by the correspondence between the reception intensity information and the reference data, while the output order of the output antenna changes for each operation of the request switch, so that the reception intensity information, for example, the reception intensity Since the change order of the values is different each time, the repeater cannot follow this, so that the relay attack is reliably prevented.

It is a block diagram which shows the structure of the vehicle side apparatus in embodiment of this invention. It is explanatory drawing which shows the reception strength state of the request signal in the position of a portable device. It is explanatory drawing which shows the change state of the output intensity value of the portable device position by the output order of an output antenna. It is a block diagram which shows the structure of a portable device. It is a flowchart which shows the flow of control in a vehicle side apparatus. It is a flowchart which shows the flow of control in a portable device.

Embodiments of the present invention will be described below.
The keyless entry device is composed of a vehicle-side device and a portable device. The keyless entry device transmits and receives request signals from the vehicle-side device and answer signals from the portable device by wireless communication, authenticates the correspondence between the vehicle and the portable device, and then opens the door. Automatically control the lock. The request signal is LF (for example, 125-135 KHz), and the answer signal is RF (for example, UHF band).
In particular, the vehicle-side device sequentially outputs request signals from a plurality of output antennas arranged at different positions on the vehicle body, and the portable device returns reception intensity information of the sequentially received request signals as an answer signal. When the change order of the received intensity values corresponds to the output order of the output antennas that output the request signals, it is determined that the portable device (and thus the owner) is located in the vicinity of the vehicle, and the door lock is unlocked. .
Note that the control target of the keyless entry device includes the engine start and the steering lock in addition to the door lock, but only the unlocking of the door lock will be described here.

Details will be described below. FIG. 1 is a block diagram showing the configuration of the vehicle side device.
The vehicle-side device 1 receives a request switch 5 installed in a vehicle body, a keyless controller 10 that generates a request signal based on the operation of the request switch 5, an output antenna 7 that outputs the request signal as a radio wave, and an answer signal Input antenna 8 and a door lock actuator 9 driven and controlled by a keyless controller 10.

The request switch 5 is installed on the back door, the DR door request switch (DRSW) 5a installed on the driver's seat door so that it can be operated from the outside of the vehicle, the AS door request switch (ASSW) 5b installed on the passenger seat door, and the back door. BK door request switch (BKSW) 5c, for example, has a form of a button that is turned on by pushing or touching.
The output antenna 7 includes a DR door output antenna 7a installed at the driver's door, an AS door output antenna 7b installed at the passenger's door, a BK door output antenna 7c installed at the back door, and an indoor center portion. The indoor output antenna 7d and the luggage output antenna 7e installed at the back of the luggage room are provided.

The keyless controller 10 is connected to the CPU 11, the LF transmitter 13 that outputs the request signal generated by the CPU 11 from the output antenna 7 (7 a, 7 b, 7 c, 7 d, 7 e) as an LF radio wave, and the answer signal connected to the input antenna 8. Is received and sent to the CPU 11.
The LF transmitter 13 includes an amplifier (not shown) corresponding to each of the output antennas 7a, 7b, 7c, 7d, and 7e. The output intensity of each output antenna 7a, 7b, 7c, 7d, 7e is set to be the same.
The keyless controller 10 further includes a memory 12 that stores a control program, an ID of a portable device 30 (see FIG. 4 described later), and the like, and temporarily stores various data being controlled, and an actuator drive circuit 15.

The CPU 11 includes a control unit 20, a switch determination unit 21, a request signal generation unit 22, an encryption processing unit 23, an output intensity value sequence calculation unit 24, and an electric field intensity value sequence comparison unit 25. The control unit 20 includes a timer (not shown).
Although connection lines are not shown, each processing unit in the CPU 11 basically stores the processing results in the memory 12 in principle even if not specifically described, and reads out necessary data and processing targets from the memory 12. The stored data is reset after the control is completed.

The switch determination unit 21 determines which of the request switches 5 (5a, 5b, 5c) has been operated.
The control unit 20 controls the CPU 11 as a whole, and at the same time outputs a request signal, generates a cipher such as a random number, and randomly determines the output order of the request signal from the output antenna 7.
The encryption processing unit 23 performs calculation processing of the encryption generated by the control unit 20 by a predetermined calculation process incorporating the ID of the corresponding portable device 30.

The request signal generation unit 22 generates a request signal every time the request switch 5 is operated, and controls the LF transmission unit 13 to output from each output antenna 7 in the output order determined by the control unit 20.
The request signal includes an information signal including a wake-up signal and a cipher generated by the control unit 20 and a signal for electric field strength measurement such as a burst wave. The information signal is a request signal output at the beginning of a series of output orders. If included, the request signal after the second output may be only the electric field strength measurement signal.
The wakeup signal includes a predetermined transmission time that is set in advance until the output of request signals from all the output antennas 7 is completed.

The output intensity value string calculation unit 24 calculates the electric field intensity value string at the representative position (described later) of the operated request switch 5 with respect to the series of request signals (electric field intensity measurement signals) output in the above output order. This is the output intensity value sequence.
That is, even if the output intensity of each of the output antennas 7a, 7b, 7c, 7d, and 7e is fixed to be the same, the electric field intensity (RSSI) is attenuated according to the distance from the antenna, and therefore varies depending on the reception position. Therefore, depending on which request switch 5 is operated, the electric field strength at the position of the portable device 30 held by the operator is different even for signals from the same output antenna 7.

Therefore, as the position of the portable device 30 held by the operator, the position near the request switch is set in advance as the “representative position of the request switch” for each of the request switches 5a, 5b, and 5c. The electric field intensity values of the electric field intensity measurement signals from the output antennas 7a, 7b, 7c, 7d, and 7e are obtained by actual measurement or calculation, respectively.
A series of calculated electric field intensity values, that is, output intensity value sequences are stored in the memory 12.

FIG. 2 shows, by way of example, the electric field strength of a radio wave (request signal) at the position of the portable device 30 when the AS door request switch 5b is operated, in magnitude of level, and (a) shows the output from the DR door output antenna 7a. (B) is output from the AS door output antenna 7b, (c) is output from the BK output antenna 7c, (d) is output from the indoor output antenna 7d, and (e) is output from the luggage output antenna 7e. It is the electric field strength of each radio wave at the time of output.
The portable device possessed by the operator is located in the vicinity of the AS door request switch 5b that is naturally operated. Therefore, since the distance Sb between the portable device and the AS door output antenna 7b is short, the electric field strength at the time of output from the antenna is high, and conversely, the distance Sa between the portable device and the DR door output antenna 7a is long, so Therefore, the electric field strength at the time of output becomes a small level. Since the distances Sc and Se between the portable device and the BK output antenna 7c and the luggage output antenna 7e are also long, the electric field strength is low, and the distance between the portable device and the indoor output antenna 7d is intermediate. The electric field strength of becomes a medium level.

The request signal output order of the output antenna 7 is AS door output antenna 7b (AS) -DR door output antenna 7a (DR) -BK door output antenna 7c (BK) -room output antenna 7d (RM) -luggage output antenna 7e (LG ), The electric field intensity (output intensity value) at the position of the portable device is an output intensity value string whose level changes in the order of large-small-small-medium-small as shown in FIG. Form.
Also, the output order of the output antenna 7 is changed, and the electric field strength when the order of BK door output antenna 7c-AS door output antenna 7b-DR door output antenna 7a-luggage output antenna 7e-indoor output antenna 7d is shown in FIG. As shown in (b), the level changes in the order of small-large-small-small-medium.
When the other request switches 5a and 5c are operated, the position of the portable device also changes naturally, the electric field strength varies depending on the distance from each output antenna 7, and the level change of the electric field strength similarly depends on the output order of the output antennas 7. The order of changes.

  Returning to FIG. 1, the electric field intensity value string comparison unit 25 includes a received intensity value string, which will be described later, included in the answer signal from the portable device for the request signal, and an output intensity value string previously stored in the memory 12. Compare. Then, it is determined whether or not the change order of the reception intensity in the reception intensity value sequence corresponds to the output order of the output antenna 7 that has output the request signal.

Regarding the reception of the answer signal, the control unit 20 confirms whether the answer signal is from a portable device corresponding to the vehicle including the keyless controller 10 based on a later-described cryptographic processing result included in the answer signal.
That is, the cipher included in the request signal is stored in the memory 12 as the vehicle-side cipher processing result by the cipher processing unit 23 processed by the same calculation process as the cipher processing unit 41 (see FIG. 4) of the portable device. The control unit 20 compares the encryption processing result from the portable device 30 with the vehicle-side encryption processing result, and authenticates that it is from the corresponding portable device 30 if they are the same.
Furthermore, when the reception intensity change sequence of the received intensity value sequence corresponds to the output order of the output antenna 7 as a result of the determination by the electric field intensity value sequence comparing unit 25, it is assumed that the answer signal is transmitted from the vicinity of the vehicle. 20 sends a drive command to the actuator drive circuit 15.

FIG. 4 is a block diagram showing the configuration of the portable device 30.
The portable device 30 is configured as an integrated unit in which an input antenna 32 and an output antenna 33 are connected to a remote controller 31.
The remote controller 31 causes the CPU 35, the LF receiver 37 that is connected to the input antenna 32 to receive a request signal, the reception intensity detector 38 that detects the reception intensity of the request signal, and the answer signal to be output from the output antenna 33. An RF transmission unit 39 and a memory 36 that stores the control program and the ID of the portable device 30 are provided.

In particular, the CPU 35 controls the entire control unit 40, a cryptographic processing unit 41 that processes the encryption of the request signal in a predetermined calculation process incorporating the ID of the portable device 30, and an answer signal generation unit 42 that generates an answer signal. The control unit 40 includes a timer (not shown).
Similarly to the vehicle-side device 1, each unit in the CPU 35 temporarily stores the processing result in the memory 36, and reads out necessary data and a processing target from the memory 36. The stored data is reset after the control is completed.
The portable device 30 can also be provided with a control switch for transmitting a control command for locking / unlocking the door of the vehicle or starting the engine from a remote location, but illustration and description thereof are omitted.

Although the remote controller 31 is in a normal sleep state, when a request signal is received, the remote controller 31 shifts to a normal operation state in response to a wake-up signal included in the request signal.
In the CPU 35, the control unit 40 starts the timer count, and the reception intensity detection unit 38 detects the reception intensity value of the electric field intensity measurement signal of the request signal, and sequentially stores it in the memory 36.
The encryption processing unit 41 calculates the encryption of the request signal by a predetermined calculation process incorporating the ID of the portable device 30.

When the predetermined transmission time included in the wakeup signal elapses due to the timer count, the answer signal generation unit 42 receives an answer signal including the result of the encryption processing by the encryption processing unit 41 and the received intensity value sequence in the reception order stored in the memory 36 Is sent to the RF transmitter 39, whereby a response to the request signal is made.
After returning the answer signal, the remote controller 31 returns from the normal operation state to the sleep state.

  In the keyless controller 10 on the vehicle side, after outputting a request signal from all the output antennas 7a, 7b, 7c, 7d, and 7e, if the answer signal is received within a certain time (response waiting time), the control unit 20 performs encryption processing. After authenticating based on the result, the electric field intensity value string comparison unit 25 compares the received intensity value string and the output intensity value string to determine whether or not the answer signal is transmitted from the vicinity of the vehicle.

FIG. 5 is a flowchart showing the flow of control in the keyless controller 10 of the vehicle side device 1 for the automatic unlocking of the door, in particular the CPU 11 thereof.
As described above, the memory 12 stores in advance the ID of the corresponding portable device 30, the predetermined transmission time, and the field strength value from each output antenna 7 at the representative position of each request switch 5.
The CPU 11 starts this control when the control unit 20 detects the ON operation of the request switch 5.

First, in step 100, the switch discriminating unit 21 discriminates which of the request switches 5a, 5b, 5c has been operated, and stores it in the memory 12.
In step 101, the control unit 20 sets a random output order of the encryption and the output antenna 7 and stores them in the memory 12.
Subsequently, in step 102, the request signal generator 22 controls the LF transmitter 13 to output request signals from the output antennas 7 at predetermined time intervals in the set output order. At this time, the first request signal includes a wakeup signal and encryption including a predetermined transmission time in addition to the electric field strength measurement signal, but the second and subsequent request signals do not require a wakeup signal and encryption. It is.

During the sequential output of the request signals, in step 103, the cryptographic processing unit 23 calculates the cipher and stores the result in the memory 12 as the vehicle side cryptographic processing result. In step 104, the output strength value string calculating unit 24 Reads the field intensity value from each output antenna 7 at the representative position of the operated request switch 5 from the memory 12, calculates an output intensity value sequence arranged in the output order, and stores it in the memory 12.
For example, the AS door request switch 5b is operated, and the output order of the output antenna 7 is AS door output antenna 7b (AS) -DR door output antenna 7a (DR) -BK door output antenna 7c (BK) -room output antenna 7d (RM )-When the order of the luggage output antenna 7e (LG) is set, as shown in FIG. 3A, the output intensity value in which the level changes in the order of large-small-small-medium-small A column is calculated and stored.

When all the request signals are output, in step 105, the control unit 20 starts timer counting, and in step 106, it is checked whether a preset response waiting time has elapsed.
If the response waiting time has not elapsed, in step 107, the control unit 20 checks whether an answer signal has been received.
If no answer signal has been received, the process returns to step 106. When the response waiting time elapses without receiving an answer signal, the current control process is terminated.

When the answer signal is received, the process proceeds to step 108, and the control unit 20 collates the encryption processing result included in the answer signal with the vehicle-side encryption processing result stored in the memory 12.
As a result of the collation, when it is confirmed that the answer signal is from the corresponding portable device 30, the process proceeds to step 109.
In step 109, the electric field intensity value string comparison unit 25 compares the received intensity value string included in the answer signal with the output intensity value string stored in the memory 12, and whether or not the change order of both matches. Check.
Here, the level change of the received intensity value sequence is matched in the order of “large-small-small-medium-small” with respect to the level change of the output intensity value sequence “large-small-small-medium-small”. For example, in step 110, the control unit 20 outputs a door lock drive command to the actuator drive circuit 15.
Thereby, the door lock actuator 9 unlocks the locked door lock, and this control is finished.

The actuator drive circuit receives the drive command as described above when the door is locked and unlocks the door lock, but locks when the door is unlocked.
On the other hand, if the change order of the received intensity value sequence and the output intensity value sequence does not correspond, the drive command is output assuming that the portable device is not located near the vehicle, that is, the owner of the portable device is not located near the vehicle. Exit without

Next, FIG. 6 is a flowchart showing the flow of control in the remote controller 31 of the portable device 30, particularly the CPU 35 thereof.
The remote controller 31 receives the wakeup signal of the request signal, shifts from the sleep state to the normal operation state, and starts this control.
First, at step 200, the control unit 40 extracts the encryption of the information signal and the predetermined transmission time from the request signal and stores them in the memory 36.
In step 201, the control unit 40 starts timer counting, and in step 202, the cryptographic processing unit 41 performs calculation processing on the cipher according to a predetermined calculation process, and stores the cryptographic processing result in the memory 36.

In step 203, the control unit 40 checks whether a predetermined transmission time has elapsed.
When the predetermined transmission time has not elapsed, the routine proceeds to step 204 where the reception intensity detection unit 38 detects the reception intensity value of the electric field intensity measurement signal for each received individual request signal, and sequentially stores it in the memory 36. And then return to step 203. Each time a request signal is received, steps 203 and 204 are repeated.
If the predetermined transmission time has elapsed in the check in step 203, the process proceeds to step 205.
In step 205, the answer signal generation unit 42 generates an answer signal including a received intensity value sequence in which received intensity values stored in the memory 36 are arranged in the order of reception, and a cryptographic processing result.
In step 206, the answer signal generator 42 outputs the answer signal from the output antenna 33 via the RF transmitter 39, and then shifts to the sleep state and ends the control.

With the above control, first, for authentication, a predetermined calculation in which the cipher included in the request signal from the vehicle-side device 1 is incorporated into the ID of the portable device 30 without transmitting raw ID data from the portable device 30. The result of calculation processing in the process is returned, and the vehicle-side device 1 also performs calculation processing of the encrypted data in the same calculation process and collates it with the result, so there is no possibility that the ID of the portable device 30 is stolen by a third party. .
In addition, since the predetermined transmission time corresponding to the completion of the output of the request signals from all the output antennas 7 and the response waiting time associated therewith are set, the portable device 30 immediately receives the request signal from the completion of reception. Answer signals can be sent back, and high security can be obtained by eliminating illegal signals from third parties that take time to analyze request signals.

In this embodiment, the received intensity value sequence corresponds to the received intensity information in the invention, and the output intensity value sequence corresponds to the reference data.
Steps 101 and 102 in the flowchart of FIG. 5 constitute request signal generation means in the invention, step 104 constitutes reference data calculation means, and step 109 constitutes position confirmation means.
Further, step 204 in the flowchart of FIG. 6 constitutes reception intensity detection means, and step 205 constitutes answer signal generation means.

The embodiment is configured as described above, and the vehicle-side device 1 that outputs a request signal from the output antenna 7 based on the operation of the request switch 5 installed in the vehicle, and an answer signal is returned in response to the request signal. In a keyless entry device comprising a portable device 30 and authenticating that the vehicle-side device 1 and the portable device 30 are compatible and driving a door lock, the output antenna 7 (7a to 7e) is placed at different positions on the vehicle body. And the vehicle-side device 1 changes the output order of the plurality of output antennas 7 for each operation of the request switch 5, and the portable device 30 includes a received signal strength value sequence of the request signal in the answer signal. In the side device 1, the received intensity value sequence corresponds to the output intensity value sequence calculated based on the output order of the output antenna 7, so that the portable device 30 is close to the vehicle. Make sure that you are located in, was assumed for driving the door lock.
That is, even if the output intensity of each output antenna 7 is fixed to be the same, the received intensity varies depending on the position of the portable device 30, so that a received intensity value sequence whose level varies depending on the output order of the output antenna 7 is obtained. Therefore, it is not necessary to provide the vehicle side device 1 with a circuit for changing the output of the request signal in order to change the reception intensity of the request signal, and the complexity of the configuration and the increase in cost can be avoided.
In a circuit that changes the output, there is a possibility that the output is lowered too much and the portable device cannot receive the signal. However, since the output intensity may be fixed, there is no possibility that the signal cannot be received.
And since it confirms that the portable device 30 is located in the vicinity of the vehicle by matching the change order of the received intensity value sequence and the change order of the output intensity value sequence, the request signal output level of the vehicle side device 1 is Even if there is some variation in the reception level of the portable device 30, it is easy and reliable to determine matching.
In addition, it is difficult to accurately transmit the reception intensity of the request signal with a repeater that converts the LF reception signal into RF and transmits it. However, the change state of the reception intensity of the request signal is measured in advance for a specific vehicle. Even if an unauthorized attempt is made to include in the relay information, the received intensity value sequence changes depending on the output order of the output antenna 7 every time the request switch 5 is operated. Relay attack is reliably prevented.
(Effects corresponding to claims 1, 2, 6 and 7)

The request switches 5 are arranged on the driver's seat door, the passenger seat door, and the back door, and for each request switch 5, the electric field intensity value from each output antenna 7 in the vicinity is obtained, and which request switch 5 is operated. Since the output intensity value string to be compared with the received intensity value string is calculated depending on whether or not the request switch 5 is operated by approaching an arbitrary door, the position of the portable device 30 is correctly confirmed, and the door can be opened from any door. Lock control is possible.
(Effects corresponding to claims 4 and 9)

The portable device 30 includes the encryption in the answer signal to the vehicle side device 1 by including the encryption in the request signal, and the portable device 30 includes the encryption processing result obtained by calculating the encryption by the calculation process incorporating the ID. It is verified that the portable device 30 is registered in the vehicle-side device 1 by comparing the result of calculation processing of the above cipher with the same calculation process as that of the answer signal 30 and the encryption processing result of the answer signal. Therefore, there is no possibility that the ID of the portable device 30 is stolen by a third party.
(Effects corresponding to claim 5)

Since the request signal includes the electric field strength measurement signal, it is easy to detect the reception strength value of each request signal.
(Effects corresponding to claim 10)

In the embodiment, the number of output antennas 7 is five at specific positions, but the number and installation positions may be appropriately set according to the vehicle type, the vehicle body structure, and the like.
In the request signal, the wakeup signal includes a predetermined transmission time until the output of the request signal from all the output antennas 7 is completed. However, the request signal is not limited thereto, and the transmission from the vehicle side device 1 is completed. Can be used as an index for immediately shifting to answering of the answer signal after confirmation on the portable device 30 side, information on the number of request signals, the number of output antennas 7, or a transmission completion signal following the last request signal Etc.

  In the authentication of the correspondence relationship between the vehicle side device 1 and the portable device 30, the cryptographic processing result in the portable device 30 is verified on the vehicle side device 1 side. It is also possible to transmit the result of the cryptographic processing by the incorporated calculation process to the portable device 30 and not return an answer signal unless the result is verified by the portable device 30 side.

In the embodiment, the portable device 30 calculates the reception intensity value sequence and includes it in the answer signal after completing the reception of the request signals from all the output antennas 7. However, the present invention is not limited to this. Each time the individual request signal from the output antenna 7 is received, the received intensity value is returned as an answer signal each time, and the vehicle side apparatus 1 sequentially accumulates the received intensity values in the memory 12 and then arranges them in the order in which the answer signals are received. A reception intensity value sequence may be obtained.
Even in this case, it is possible to confirm that the portable device 30 is located in the vicinity of the vehicle by finally comparing the received intensity value string and the output intensity value string and matching the change order. Has the same effect as the form.
(Effects corresponding to claims 3 and 8)

DESCRIPTION OF SYMBOLS 1 Vehicle side device 5 Request switch 5a DR door request switch 5b AS door request switch 5c BK door request switch 7 Output antenna 7a DR door output antenna 7b AS door output antenna 7c BK door output antenna 7d Indoor output antenna 7e Luggage output antenna 8 Input Antenna 9 Door lock actuator 10 Keyless controller 11 CPU
DESCRIPTION OF SYMBOLS 12 Memory 13 LF transmission part 14 RF receiving part 15 Actuator drive circuit 20 Control part 21 Switch discrimination | determination part 22 Request signal generation part 23 Cryptographic process part 24 Output intensity value sequence calculation part 25 Electric field strength value string comparison part 30 Portable machine 31 Remote controller 32 Input antenna 33 Output antenna 35 CPU
36 Memory 37 LF Receiver 38 Received Strength Detector 39 RF Transmitter 40 Control Unit 41 Encryption Processing Unit 42 Answer Signal Generation Unit

Claims (10)

It consists of a vehicle side device that outputs a request signal based on the operation of a request switch installed in the vehicle, and a portable device that returns an answer signal in response to the request signal. It is a control method of a keyless entry device that authenticates and drives a door lock,
The vehicle-side device arranges a plurality of output antennas that output the request signals at different positions of the vehicle body, and changes the output order of the plurality of output antennas for each operation of the request switch.
The portable device includes reception intensity information of the request signal in the answer signal,
The vehicle-side device further controls the keyless entry device after confirming that the received intensity information corresponds to reference data based on the output order of the output antennas, and then drives the door lock. Method. The portable device returns a response signal after receiving a series of request signals sequentially output from the plurality of output antennas,
The reception strength information is a reception strength value sequence in which the reception strength values of the request signals are arranged in the order of reception;
The reference data is an output intensity value sequence in which electric field intensity values obtained in advance of request signals from the output antenna at positions near the request switch are arranged in the output order,
2. The method of controlling a keyless entry device according to claim 1, wherein the reception intensity information corresponds to reference data when a change order of the reception intensity value string and the output intensity value string matches. The portable device returns the answer signal every time it receives individual request signals sequentially output from the plurality of output antennas,
The received strength information is a received strength value of the individual request signal;
In the vehicle side device, the reception strength value sequence in which the reception strength values are arranged in the order of reception of the answer signals is calculated,
The reference data is an output intensity value sequence in which electric field intensity values obtained in advance of request signals from the output antenna at positions near the request switch are arranged in the output order,
2. The method of controlling a keyless entry device according to claim 1, wherein the reception intensity information corresponds to reference data when a change order of the reception intensity value string and the output intensity value string matches. A plurality of the request switches are arranged at different positions on the vehicle body, and the electric field strength value is obtained for each request switch,
4. The keyless entry device control method according to claim 2, wherein the output intensity value sequence is calculated according to an operated request switch. Including encryption in the request signal;
The portable device includes in the answer signal a cryptographic processing result obtained by calculating the cipher in a calculation process incorporating the ID of the portable device,
5. The vehicle-side apparatus performs the authentication by comparing a result of calculation processing of the cipher with the same calculation process as the calculation process and an encryption processing result of the answer signal. 6. The control method of the keyless entry apparatus of any one. It consists of a vehicle side device that outputs a request signal based on the operation of a request switch installed in the vehicle, and a portable device that returns an answer signal in response to the request signal. A keyless entry device that authenticates and drives the door lock,
The vehicle side device
While arranging a plurality of output antennas that output the request signal at different positions of the vehicle body,
Request signal generating means for changing the output order of the output antenna for each operation of the request switch and outputting the request signal;
Reference data calculating means for calculating reference data based on the output order of the output antennas;
Position confirmation means for confirming the position of the portable device;
The portable device is
Reception intensity detection means for detecting the reception intensity of the request signal;
An answer signal generating means for returning the answer signal including reception intensity information based on a detection result of the reception intensity detection means;
The position confirmation means confirms that the portable device is located in the vicinity of the vehicle by the reception intensity information included in the answer signal corresponding to the reference data, and drives the door lock by the confirmation. Keyless entry device. The answer signal generating means generates the answer signal after receiving a series of request signals sequentially output from the plurality of output antennas, and obtains an individual received intensity value of the request signal detected by the received intensity detecting means. A reception strength value sequence arranged in the order of reception is included in the answer signal as the reception strength information,
The reference data is an output intensity value sequence in which electric field intensity values obtained in advance of request signals from the output antenna at positions near the request switch are arranged in the output order,
The said position confirmation means judges that the said receiving strength information respond | corresponds to reference data, when the change order of the said receiving strength value row | line | column and an output strength value row | line | column corresponds. Keyless entry device. The answer signal generation means generates the answer signal every time receiving individual request signals sequentially output from the plurality of output antennas, and receives the individual reception strengths of the request signals detected by the reception strength detection means. A value is included in the answer signal as the received strength information,
The reference data is an output intensity value sequence in which electric field intensity values obtained in advance of request signals from the output antenna at positions near the request switch are arranged in the output order,
The position confirmation means calculates a received intensity value sequence in which the received intensity values are arranged in the order of reception of the answer signals, and the received intensity information indicates when the received intensity value sequence and the change order of the output intensity value sequence match. The keyless entry device according to claim 6, wherein the keyless entry device is determined to correspond to the reference data. A plurality of the request switches are arranged at different positions on the vehicle body,
The keyless entry device according to claim 7 or 8, wherein the reference data calculation means calculates the output intensity value sequence in accordance with an operated request switch. The request signal generation means includes an electric field strength measurement signal in the request signal output from each antenna,
The keyless entry device according to any one of claims 6 to 9, wherein the reception intensity detecting unit detects a reception intensity value of the electric field intensity measurement signal.

Images