JP2013217045A - Portable machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable machine which easily receives a radio signal.SOLUTION: When a request signal from a vehicle 10 is recognized, an electronic key 20 transmits a response signal as a response to the request signal. The electronic key 20 comprises antennas 22x, 22y and 22z and an electronic key control section 21. The antennas 22x, 22y and 22z are switched between a standby state where the request signal can be received and a non-standby state where the request signal cannot be received. The number of antennas to be brought into the standby state and to be brought into the non-standby state, among the antennas 22x, 22y and 22z is one. When the request signal cannot be received via the antenna brought into the standby state, the electronic key control section switches the antenna in the standby state into the non-standby state and switches the antenna in the non-standby state into the standby state.

Description

  The present invention relates to a portable device capable of operating a mounted device to be communicated by performing wireless communication with a communication target.

  Patent Document 1 discloses an electronic key (portable device) that performs wireless communication with a vehicle. When wireless communication with the electronic key is established, the vehicle permits locking / unlocking of the vehicle door, engine starting, and the like. For example, the vehicle wirelessly transmits a wake signal around the vehicle while the vehicle is stopped. When receiving the wake signal, the electronic key wirelessly transmits an ACK signal indicating that the wake signal has been received. When the vehicle receives the ACK signal, the vehicle wirelessly transmits a request signal requesting the ID code. When receiving the request signal, the electronic key wirelessly transmits a response signal including its own ID code. When the vehicle receives the response signal, the vehicle collates the ID code included in the response signal with its own ID code. And when collation is materialized, locking and unlocking of a vehicle door are permitted. In this state, for example, when the operation of a switch provided on the door handle is detected, the vehicle switches the locking / unlocking state of the vehicle door.

JP 2005-194799 A

  Some electronic keys employ three antennas that are orthogonal to each other as antennas for receiving radio signals. Since the three antennas have three-axis sensitivity directions, it is easier to receive a radio signal than when there is only one antenna. On the other hand, when all three antennas maintain the reception state, the power consumption of the battery of the electronic key increases. Further, it is only necessary that a wireless signal can be received by any one of the three antennas. Therefore, the electronic key uses the reception of the wake signal to select an antenna that can receive the wake signal from the vehicle, and receives the request signal using the selected antenna.

  However, since the electronic key is carried by the user, the situation in which the electronic key receives a signal changes with time. In other words, the receiving antenna that has received the wake signal does not necessarily receive the request signal suitably.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a portable device that can easily receive a radio signal.

  In order to solve the above-mentioned problem, the invention of claim 1 is a standby state in which a mobile device that transmits a response signal as a response corresponding to a request signal from a communication master can receive the request signal. And the number of antennas that can be switched between the non-standby state in which the request signal cannot be received and the number of antennas that are set to the standby state and the non-standby state among the plurality of antennas are predetermined. When the request signal cannot be received through the antenna in the standby state, the control unit switches the antenna in the standby state to the non-standby state and switches the plurality of antennas in the non-standby state to the standby state. And a circuit.

  According to this configuration, when the portable device cannot recognize the reception of the request signal, the portable device switches the antenna that receives the request signal. Thereby, the portable device can receive the request signal more easily than maintaining the state of the antenna that cannot receive the request signal in the standby state.

  According to a second aspect of the present invention, in the portable device according to the first aspect, when the portable device recognizes a first request signal from the communication master, the portable device transmits a first response signal as a corresponding response. When the second request signal from the communication master is recognized after the transmission of the first response signal, a second response signal is transmitted as a response thereto. The control circuit When there are more antennas that are judged to be able to receive the request signal than the set number that should be set to the standby state, the set number of antennas are set to the standby state, and the other antennas are set to the non-standby state and set to the standby state. When the second request signal cannot be received by the antenna in the state, the antenna determined to be able to receive the first request signal among the antennas in the non-standby state is preferentially waited from the non-standby state. And summarized in that to switch to state.

  An antenna that has received the first request signal is more likely to receive the second request signal than an antenna that has not received the first request signal. According to this configuration, the control circuit preferentially switches the antenna that is likely to receive the second request signal from the non-standby state to the standby state. For this reason, the portable device is easier to receive the second request signal than switching to another antenna.

  According to a third aspect of the present invention, in the portable device according to the first or second aspect, when the portable device recognizes a first request signal from the communication master, a first response signal is generated as a corresponding response. When the second request signal from the communication master is recognized after the transmission of the first response signal, a second response signal is transmitted as a response to the second request signal. The gist is to switch the antenna from the non-standby state to the standby state in descending order of the signal strength of the first request signal.

  An antenna that has received a first request signal having a high signal strength is more likely to receive a second request signal having a higher signal strength than an antenna that has received a first request signal having a low signal strength. According to this configuration, the control circuit switches the antenna having a high possibility of receiving the second request signal having a high signal strength from the non-standby state to the standby state. For this reason, the portable device is easier to receive the second request signal than switching to another antenna.

  The present invention can provide a portable device that can easily receive a radio signal.

The block diagram which shows schematic structure of an electronic key system. The flowchart which shows the process of an electronic key control part. The time chart which shows the signal strength of the request signal which each antenna receives, and switching of the standby state of each antenna and a non-standby state. The time chart which shows the signal strength of the request signal which each antenna receives, and switching of the standby state of each antenna and a non-standby state. The time chart which shows the signal strength of the request signal which each antenna receives, and switching of the standby state of each antenna and a non-standby state.

Hereinafter, an embodiment in which a portable device according to the present invention is embodied as an electronic key that performs wireless communication with a vehicle will be described with reference to FIGS.
As shown in FIG. 1, the vehicle 10 is equipped with an electronic key system 1 that executes ID verification using a radio signal communicated with the electronic key 20. The electronic key system 1 has a smart communication function that executes ID verification using a radio signal from the vehicle 10 as a trigger.

<Vehicle configuration>
The vehicle 10 includes an in-vehicle control unit 11 that controls various in-vehicle devices, an LF transmission unit 12 that is electrically connected to the in-vehicle control unit 11 and transmits a request signal of an LF (Low Frequency) band, and an UHF (Ultra). And a UHF receiver 13 for receiving a response signal of a high frequency) band. The request signal is a generic term for the wake signal Swk and the request signal Srq, and the response signal is a generic term for the ack signal Sac and the response signal Sre. The LF transmission unit 12 includes an LF transmission antenna. The LF transmission unit 12 modulates a pulse signal as a request signal generated by the in-vehicle control unit 11 and wirelessly transmits the modulated signal via the LF transmission antenna. The UHF receiving unit 13 has a UHF receiving antenna. The UHF receiver 13 receives a UHF band radio signal through the UHF receiving antenna and demodulates the received signal into a pulse signal.

  The vehicle 10 also includes a door lock device 14 and a door handle sensor 15 that are also electrically connected to the in-vehicle controller 11. The door lock device 14 switches between locking and unlocking the vehicle door. The door handle sensor 15 detects contact of a user with a door handle (not shown).

  The in-vehicle control unit 11 is provided with a nonvolatile memory 11a. An ID code unique to the vehicle 10 is stored in the memory 11a. The in-vehicle controller 11 performs wireless communication with the electronic key 20 through the LF transmitter 12 and the UHF receiver 13. The in-vehicle control unit 11 determines whether or not the electronic key 20 that is in communication corresponds to itself through transmission / reception of a radio signal performed with the electronic key 20. This determination is made by collating the ID code included in the wireless signal from the electronic key 20 with the ID code stored in the memory 11a. And when it is judged that it corresponds to self, operation of door lock device 14 is permitted. Specifically, the in-vehicle control unit 11 periodically transmits a wake signal Swk. Then, when receiving the ACK signal Sac as a response to the wake signal Swk, the in-vehicle control unit 11 transmits the request signal Srq a plurality of times, here three times. When receiving the response signal Sre after transmitting the request signal Srq, the in-vehicle control unit 11 permits the operation of the door lock device 14 when determining that the response signal Sre is from the electronic key 20 corresponding to itself. . In this state, when contact with the door handle is detected through the door handle sensor 15, the in-vehicle controller 11 executes the operation of the door lock device 14.

<Structure of electronic key>
The electronic key 20 includes an electronic key control unit 21 configured by a computer unit including a CPU or the like. The electronic key control unit 21 is electrically connected to an LF reception unit 22 that receives a radio signal in the LF band and a UHF transmission unit 23 that transmits a radio signal in the UHF band. The LF receiving unit 22 includes an LF receiving antenna 22a. The LF reception unit 22 receives an LF band radio signal through the LF reception antenna 22a, and demodulates the received radio signal into a pulse signal. The UHF transmission unit 23 includes a UHF transmission antenna 23a. The UHF transmission unit 23 modulates a pulse signal as a response signal generated by the electronic key control unit 21, and wirelessly transmits the modulated signal via the UHF transmission antenna 23a.

  As shown in the enlarged view of FIG. 1, the LF reception antenna 22a includes an X-axis antenna 22x, a Y-axis antenna 22y, and a Z-axis antenna 22z having detection axes that are orthogonal to each other. The X-axis antenna 22x, the Y-axis antenna 22y, and the Z-axis antenna 22z receive an LF band radio signal by inducing a voltage corresponding to a change in magnetic flux along its own axial direction. The LF reception unit 22 uses the antennas 22x, 22y, and 22z to receive a LF-band radio signal by consuming battery power (not shown), and to transmit an LF-band radio signal without consuming battery power. Switch between non-standby states that do not receive.

  Further, as shown in FIG. 1, the LF receiver 22 is provided with an RSSI circuit 22b that detects a value of a received signal strength (RSSI) of a received radio signal. The RSSI circuit 22b detects an RSSI value of a radio signal received via each of the X-axis antenna 22x, the Y-axis antenna 22y, and the Z-axis antenna 22z. Then, the detection result is output to the electronic key control unit 21.

The electronic key control unit 21 includes a non-volatile memory 21a, and an ID code unique to the electronic key 20 and a unique wake pattern are stored in the memory 21a.
The electronic key control unit 21 performs received signal strength determination (RSSI determination) of the wake signal Swk received by the respective antennas 22x, 22y, and 22z together with pattern determination. The electronic key control unit 21 exceeds the signal intensity (necessary signal intensity) necessary for suitably reading a preset received signal in any of the X-axis antenna 22x, the Y-axis antenna 22y, and the Z-axis antenna 22z. When a radio signal is received, the antenna that receives the radio signal is selected as an antenna to be used for communication. When a plurality of antennas receive a radio signal having the required signal strength, an antenna to be used for communication is selected according to a preset priority order. After selecting an antenna to be used for communication, the electronic key control unit 21 determines a pattern of a radio signal received by the antenna. When the received radio signal pattern matches the wake pattern stored in advance in the memory 21a, the electronic key control unit 21 recognizes the signal as the wake signal Swk. Then, the electronic key control unit 21 maintains the selected antenna in the standby state through the LF reception unit 22 and switches the other antennas from the standby state to the non-standby state.

  If the wake pattern does not match, the electronic key control unit 21 sets the antenna that has been in the standby state until now to the non-standby state, and when there is another antenna that has received a radio signal exceeding the required signal strength. Then, the gargle antenna is switched from the standby state to the non-standby state.

  When the electronic key control unit 21 recognizes the wake signal Swk, the electronic key control unit 21 generates an ACK signal Sac indicating that the signal has been received, and outputs the generated ACK signal Sac to the UHF transmission unit 23. The UHF transmission unit 23 modulates the ACK signal Sac, and wirelessly transmits the modulated ACK signal Sac via the UHF transmission antenna 23a.

  When the electronic key control unit 21 recognizes the request signal Srq after transmitting the ACK signal Sac, the electronic key control unit 21 generates a response signal Sre as a response to the signal. The response signal Sre includes the ID code stored in the memory 21a. The electronic key control unit 21 outputs the generated response signal Sre to the UHF transmission unit 23. The UHF transmitter 23 modulates the response signal Sre and wirelessly transmits the modulated response signal Sre via the UHF transmission antenna 23a.

<Switching antenna>
Next, switching between the standby state and the non-standby state of the LF reception antenna 22a (antennas 22x, 22y, 22z) will be described with reference to the flowchart shown in FIG. The flowchart is executed by the electronic key control unit 21. The electronic key control unit 21 recognizes the wake signal Swk when the radio signal pattern received by any of the antennas 22x, 22y, and 22z matches the wake pattern stored in the memory 21a in advance. This process is started. The antennas 22x, 22y, and 22z are in a standby state.

First, the electronic key control unit 21 determines whether there are a plurality of antennas that have received the wake signal Swk (step S1).
If YES in step S1, that is, if there are a plurality of antennas that have received the wake signal Swk, the electronic key control unit 21 performs RSSI determination of the wake signals Swk received by the plurality of antennas (step S2). Then, the process proceeds to step S3. Note that in step S1, NO, that is, when the number of antennas that have received the wake signal Swk is one, the electronic key control unit 21 proceeds to step S3.

  In step S3, the electronic key control unit 21 determines the switching order of the antennas 22x, 22y, and 22z. For example, when there are a plurality of antennas that have received the wake signal Swk, they are set in the order of strong RSSI of the wake signal Swk. For example, as shown in FIG. 3, when all three antennas 22x, 22y, and 22z receive a wake signal Swk that exceeds the required signal strength and the signal strength is strong in the order of antennas 22x, 22z, and 22y, antenna switching is performed. The order is the order of the antennas 22x, 22z, and 22y. Also, for example, if there is one antenna that has received the wake signal Swk exceeding the required signal strength, that antenna is set first, and the rest are set in alphabetical order. For example, as shown in FIG. 4, when the wake signal Swk exceeding the required signal strength is received by the antenna 22y and the wake signal Swk cannot be received by the other antennas 22x and 22z, the switching order of the antennas is the antennas 22y, 22x, 22z order. In addition, when there are a plurality of antennas that have received the wake signal Swk that exceeds the required signal strength and there are antennas that have not received the wake signal Swk that exceeds the required signal strength, the wake signal Swk that has exceeded the required signal strength has been received. Switch antennas preferentially. For example, as shown in FIG. 5, in the example, the wake signal Swk exceeding the required signal strength is received by the antennas 22x and 22y, the signal strength is strong in the order of the antennas 22x and 22y, and the wake signal Swk is received by the other antennas 22z. If reception is not possible, the antenna switching order is antennas 22x, 22y, and 22z.

  As shown in FIG. 2, after determining the switching order of the antennas 22x, 22y, and 22z, the electronic key control unit 21 transmits an ACK signal Sac as a response to the wake signal Swk (step S4). The electronic key control unit 21 maintains one antenna in the standby state and switches the other two antennas from the standby state to the non-standby state based on the switching order determined in step S3 (step S5).

  Next, the electronic key control unit 21 determines whether or not the request signal Srq has been recognized (step S6). If YES in step S6, that is, if the request signal Srq has been recognized, a response signal Sre is transmitted (step S7), and this series of processing ends.

  If NO in step S6, that is, if the request signal Srq cannot be recognized, the antenna for receiving the request signal Srq is selected from the two antennas that have been set to the non-standby state based on the switching order determined in step S3. While switching one to the standby state, the antenna that has been in the standby state is switched to the non-standby state (step S8), and the process proceeds to step S6.

  When the door handle sensor 15 detects contact in a state where the response signal Sre is recognized, the in-vehicle controller 11 operates the door lock device 14 to switch between locking and unlocking the vehicle door.

As described above in detail, according to the present embodiment, the following effects can be obtained.
(1) The electronic key control unit 21 selects an antenna that can receive the wake signal Swk that exceeds the required signal strength among the antennas 22x, 22y, and 22z, puts the selected antenna in a standby state, and puts the other antennas into a non-standby state. Changed to standby mode. Since the wake signal Swk and the request signal Srq are transmitted from the same vehicle 10, an antenna that can receive the wake signal Swk is highly likely to receive the request signal Srq. On the other hand, the antenna that has received the wake signal Swk that exceeds the required signal strength may not necessarily receive the request signal Srq. In this regard, when the electronic key control unit 21 cannot receive the request signal Srq after receiving the wake signal Swk, the electronic key control unit 21 switches the standby antenna to the non-standby state and the non-standby antenna to the standby state. Thereby, the electronic key control unit 21 can easily receive the request signal Srq.

  (2) The electronic key control unit 21 performs received signal strength determination (RSSI determination) of the wake signal Swk received by the antennas 22x, 22y, and 22z. The antenna that has received the wake signal Swk having the highest signal strength is maintained in the standby state, and the other antennas are switched from the standby state to the non-standby state. If the antenna that has received the wake signal Swk having the highest signal strength receives the request signal Srq, and if it cannot receive the request signal Srq, the antenna that has received the wake signal Swk having the next highest signal strength attempts to receive the request signal Srq. Since the wake signal Swk and the request signal Srq are transmitted from the same vehicle 10, an antenna having a strong signal strength of the wake signal Swk is highly likely to receive the request signal Srq. Thereby, the electronic key control unit 21 can easily receive the request signal Srq.

  (3) When the electronic key control unit 21 cannot receive the request signal Srq with the antenna switched to receive the request signal Srq, the electronic key control unit 21 sets the antenna for receiving the request signal Srq to a wake signal that exceeds the required signal strength. Switch to an antenna that could not receive Swk. Since the positional relationship between the electronic key 20 and the vehicle 10 changes due to the movement of the user or the like, the antenna that cannot receive the wake signal Swk is not necessarily unable to receive the request signal Srq. For this reason, the electronic key control unit 21 can easily receive the request signal Srq rather than trying to receive the request signal Srq while maintaining the antenna that cannot receive the request signal Srq in a standby state.

In addition, you may change the said embodiment as follows.
In the above embodiment, when the electronic key control unit 21 cannot recognize the request signal Srq, the antenna that has received the wake signal Swk among the antennas 22x, 22y, and 22z is preferentially switched from the non-standby state to the standby state. Although it switched, it does not need to give priority. That is, one of the two antennas in the non-standby state may be switched to the standby state, and the antenna that has been in the standby state may be switched to the non-standby state. Even in such a configuration, the electronic key control unit 21 can easily receive the request signal Srq, rather than trying to receive the request signal Srq while maintaining an antenna that cannot receive the request signal Srq in a standby state.

  In the above embodiment, when the electronic key control unit 21 cannot recognize the request signal Srq, the electronic key control unit 21 switches from the non-standby state to the standby state in descending order of the signal strength of the received wake signal Swk among the antennas 22x, 22y, and 22z. However, the signal strength does not have to be in descending order. That is, one of the two antennas in the non-standby state may be switched to the standby state, and the antenna that has been in the standby state may be switched to the non-standby state. Even in such a configuration, the electronic key control unit 21 can easily receive the request signal Srq, rather than trying to receive the request signal Srq while maintaining an antenna that cannot receive the request signal Srq in a standby state.

  In the above embodiment, the electronic key control unit 21 has only one antenna that has received the wake signal Swk, and when the antenna cannot receive the request signal Srq, of the antennas that have not received the wake signal Swk. The non-standby state is switched to the standby state in alphabetical order, but it may not be in alphabetical order. That is, one of the two antennas in the non-standby state may be switched to the standby state, and the antenna that has been in the standby state may be switched to the non-standby state. Even in such a configuration, the electronic key control unit 21 can easily receive the request signal Srq, rather than trying to receive the request signal Srq while maintaining an antenna that cannot receive the request signal Srq in a standby state.

  In the above embodiment, the number of antennas in the standby state for receiving the request signal Srq is one of the antennas 22x, 22y, and 22z, but may be two. Even when configured in this way, power consumption is suppressed as compared with the case where all three are set in a standby state.

  In the above embodiment, the antennas 22x, 22y, and 22z are used as the LF receiving antennas 22a, but the number is not limited to three. There may be two or more LF receiving antennas.

  In the above embodiment, the antennas 22x, 22y, and 22z are in a positional relationship that is orthogonal to each other, but the positional relationship is not limited thereto. However, if the positional relationship is orthogonal to each other, any of the antennas 22x, 22y, and 22z can easily receive the request signal from the vehicle 10.

  In the above embodiment, the request signal is a radio signal in the LF band and the response signal is a radio signal in the UHF band, but the reverse relationship may be used. Moreover, it is good also as the same frequency band. Further, it may be a radio signal belonging to a frequency band other than these. Even when configured in this manner, the same effects as those of the above-described embodiment can be obtained.

  In the above embodiment, the request signal is two types of the wake signal Swk and the request signal Srq, and the response signal is the two types of the ack signal Sac and the response signal Sre. It may be composed of the following signals.

  In the above embodiment, the in-vehicle control unit 11 transmits the request signal Srq three times after the recognition of the ACK signal Sac, but this number can be arbitrarily changed. The in-vehicle control unit 11 may transmit the request signal Srq again when the response signal Sre cannot be recognized within a predetermined time after transmission of the request signal Srq.

  In the above embodiment, the wireless communication between the vehicle 10 and the electronic key 20 is for switching the locking / unlocking of the vehicle door in the door lock device 14, but for example, on / off of the engine, etc. You may go to switch things.

  In the above embodiment, the electronic key 20 is not limited to communicating with the vehicle 10. For example, the house etc. which communicate with the electronic key 20 may be sufficient. Even when configured in this manner, the same effects as those of the above-described embodiment can be obtained.

Next, the technical idea that can be grasped from the above embodiment and other examples will be described below.
(A) In the portable device according to claim 2, when the control circuit cannot receive the second request signal even after trying all the antennas that have been determined to be capable of receiving the first request signal, A portable device that switches an antenna determined to be unable to receive the first request signal from a non-standby state to a standby state.

  Since the positional relationship between the portable device carried by the user and the communication master is constantly changing, the antenna that has received the first request signal cannot always receive the second request signal. Therefore, according to the configuration, when the antenna that has received the first request signal cannot receive the second request signal, the antenna that has not received the first request signal is switched from the non-standby state to the standby state. . This makes it easier to receive the second request signal than to maintain the previous antenna in the standby state.

  (B) The portable device according to any one of claims 1 to 3, or (a), wherein at least three of the plurality of antennas are in a positional relationship orthogonal to each other. Machine.

  According to this configuration, since the portable device includes the three antennas that are orthogonal to each other, it is easy to receive a request signal from any direction.

DESCRIPTION OF SYMBOLS 1 ... Electronic key system, 10 ... Vehicle, 11 ... Vehicle-mounted control part, 11a ... Memory, 12 ... LF transmission part, 13 ... UHF receiving part, 14 ... Door lock apparatus, 15 ... Door handle sensor, 20 ... Electronic key, 21 ... an electronic key control unit (control circuit), 21a ... memory, 22 ... LF reception unit, 22a ... LF reception antenna, 22b ... RSSI circuit, 23 ... UHF transmission unit, 23a ... UHF transmission antenna.

Claims (3)

In a portable device that transmits a response signal as a response corresponding to the request signal from the communication master,
A plurality of antennas that are switched between a standby state in which the request signal can be received and a non-standby state in which the request signal cannot be received;
Among the plurality of antennas, the number of antennas to be in a standby state and the number of antennas to be in a non-standby state is predetermined,
A control circuit that switches the standby antenna to a non-standby state when the request signal cannot be received through the standby antenna, and switches the non-standby antennas to a standby state; , A portable device comprising. The portable device according to claim 1,
When the portable device recognizes the first request signal from the communication master, the portable device transmits a first response signal as a corresponding response, and after the transmission of the first response signal, the second request from the communication master. When a request signal is recognized, a second response signal is transmitted as a response thereto,
When the number of antennas determined to be able to receive the first request signal exceeds the set number to be set in the standby state, the control circuit has the set number of antennas in the standby state, When the antenna is in a non-standby state and the second request signal cannot be received by the antenna in the stand-by state, the antenna determined to be able to receive the first request signal among the non-standby antennas is preferentially in the non-standby state. Portable device that switches from standby to standby. The portable device according to claim 1 or 2,
When the portable device recognizes the first request signal from the communication master, the portable device transmits a first response signal as a corresponding response, and after the transmission of the first response signal, the second request from the communication master. When a request signal is recognized, a second response signal is transmitted as a response thereto,
The control circuit is a portable device that switches the antenna from a non-standby state to a standby state in descending order of signal strength of the first request signal.