JP2012058844A - Short-range radio communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a short-range radio communication system which can obtain a required magnetic field intensity even when a displacing member is not completely closed.SOLUTION: In the short-range radio communication system, a secondary antenna 28 capable of relaying a transmission/reception radio wave from a primary antenna 12 provided in a vehicle to a mobile phone is provided on a door glass mounted on the vehicle, and the mobile phone and the primary antenna 12 are capable of executing short-range radio communication via the secondary antenna 28. The secondary antenna 28 has such a shape as to have a radio wave coupling part 35 for the primary antenna 12 and a radio wave input/output part and relays a transmission/reception radio wave of the primary antenna 12 and is provided with a main magnetic flux fixing structure 40 which fixes a main magnetic flux between the primary antenna 12 and the radio wave coupling part 35 of the secondary antenna 28 wherever the door glass is located within an allowable full-closing range, where the allowable full-closing range is a range in a movement direction of the door glass in which the door glass can be regarded as closed.

Description

  The present invention relates to a short-range wireless communication system that authenticates a communication terminal wirelessly.

  In recent years, a mobile phone key system has been devised in which a vehicle ID code is registered in a mobile phone and the mobile phone is used as a vehicle key (see, for example, Patent Document 1). Near field communication (NFC: Near Field Communication) communication technology is applied to this system. Then, the mobile phone is held over a reader / writer installed in the vehicle, an ID code is acquired from the mobile phone, and ID verification (holding verification) is performed using this ID code. And if ID collation is materialized, door lock locking / unlocking, engine starting operation, etc. will be permitted or performed.

  In this case, since it is necessary to determine whether the mobile phone is outside or inside the vehicle, the reader / writer is installed outside and inside the vehicle, respectively. For example, the in-vehicle reader / writer is disposed near the door in the vehicle, and the in-vehicle reader / writer is disposed in the in-vehicle center console or the like. When the mobile phone is held over the door glass from the outside of the vehicle to the reader / writer outside the vehicle, the door lock / unlock is permitted or executed when the vehicle is held and collated. When the mobile phone is held over the in-car reader / writer and the in-car check is established, engine start is permitted.

JP 2007-137135 A

  However, because the vicinity of the door can be considered as the mounting position of the reader / writer outside the vehicle, there is a limit to the installation space even when trying to increase the antenna area of the reader / writer outside the vehicle, and there is a demand for an reader / writer outside the vehicle that can ensure communication with a mobile phone. It had been. Therefore, for example, there is a short-range wireless communication system that forms a communication area different from the primary antenna by attaching a secondary antenna capable of relaying transmission / reception radio waves of the primary antenna to the door glass as an antenna in a vehicle. It has been devised. In addition, a vast space called a door glass can be effectively used as a mounting destination of the secondary antenna. Note that the communication terminal is not limited to a mobile phone, and an electronic key or the like can also be employed.

  In this case, since the secondary antenna is attached to a displacement member (movable member) called a door glass, even if the window glass is in a fully closed state, there may be cases where the positions of the windows slightly deviate from each other. At this time, there has been a problem that optimum communication cannot be performed due to a positional shift between the primary antenna and the secondary antenna. Therefore, there has been a demand for a short-range wireless communication system that can obtain a necessary magnetic field strength even if the displacement member is not completely closed.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a short-range wireless communication system capable of obtaining a necessary magnetic field strength even if a displacement member is not completely closed.

In the following, means for achieving the above object and its operational effects will be described.
According to the first aspect of the present invention, a communication master provided in a communication target and its communication terminal can communicate with each other by short-range wireless communication, and transmission / reception radio waves from a primary antenna provided in the communication target are transmitted through the communication. A secondary antenna that can be relayed to a terminal is provided on a displacement member mounted on the communication target, and the communication terminal and the primary antenna are capable of performing the short-range wireless communication via the secondary antenna. In the distance wireless communication system, the secondary antenna has a shape having annular antennas on both sides thereof by narrowing the middle of one annular antenna line, and one of these is coupled to the primary antenna by radio waves. And the other of these as a radio wave input / output unit, which relays the transmission / reception radio wave of the primary antenna and has a range in the moving direction of the displacement member that can be considered to be in a closed state. Assuming that the displaceable member is in the fully closed permissible range, the main magnetic flux between the primary antenna and the radio wave coupling portion of the secondary antenna is no matter where the displaceable member is located. The gist of the invention is that it has a main magnetic flux constant structure that keeps constant.

  According to this configuration, the shape of the secondary antenna is a shape having a radio wave coupling portion and a radio wave input / output portion, and the primary antenna and the secondary antenna are placed between the primary antenna and the secondary antenna within the permissible closed range. A main magnetic flux constant structure that stabilizes the main magnetic flux, which is a magnetic flux interlinking with both of the radio wave coupling portions, is provided. For this reason, if the displacement member is positioned within the fully closed permissible range, the main magnetic flux does not change. Further, if the magnetic flux interlinked only with either the primary antenna or the radio wave coupling part of the secondary antenna is a leakage magnetic flux, if the displacement member is located within the fully-closed allowable range, the position of the displacement member is Even in this case, since the values of the main magnetic flux and the leakage magnetic flux do not change, the coupling coefficient which is the ratio of the main magnetic flux and the leakage magnetic flux does not change. Therefore, even if the displacement member is deviated from the fully closed position, it is possible to obtain the required magnetic field strength in the secondary antenna. Note that the fully closed permissible range is a displacement range in which there is no problem even if the displacement member is deviated from the fully closed position.

  According to a second aspect of the present invention, in the short-range wireless communication system according to the first aspect, the main magnetic flux constant structure is configured so that the primary antenna and the secondary are in a fully closed permissible range in a moving direction of the displacement member. The gist is that the area of the antenna facing the radio wave coupling portion does not change.

  According to this configuration, the main magnetic flux constant structure is employed in which the facing area between the primary antenna and the radio wave coupling portion of the secondary antenna is not displaced in the fully closed allowable range. For this reason, it becomes possible to set it as the simple structure which only changes the magnitude | size of any one of a radio coupling part of a primary antenna and a secondary antenna.

  According to a third aspect of the present invention, in the short-range wireless communication system according to the first or second aspect, the main magnetic flux constant structure has an outer shape of the primary antenna within a fully closed permissible range in the moving direction of the displacement member. The gist is that the area includes the radio wave coupling portion of the secondary antenna.

  According to this configuration, it is possible to prevent the radio wave coupling portion of the secondary antenna provided on the displacement member from increasing in size. For example, it is effective when it is desired to make the radio wave input / output unit as large as possible in the displacement member.

  According to a fourth aspect of the present invention, in the short-range wireless communication system according to the first or second aspect, the main magnetic flux constant structure is configured so that the secondary antenna has the fully closed permissible range in the moving direction of the displacement member. The gist is that the primary antenna is included in the outer area of the radio wave coupling portion.

According to this configuration, it is possible to suppress an increase in the size of the primary antenna. For example, it is effective when it is desired to avoid exposing the primary antenna as much as possible.
According to a fifth aspect of the present invention, in the short-range wireless communication system according to the fourth aspect, conductive conductive plates are installed on at least both sides of the primary antenna in the moving direction of the displacement member. Is the gist.

  According to this configuration, since the conductor plates are provided on at least both sides of the primary antenna in the moving direction of the displacement member, the main magnetic flux, which is a magnetic flux linked to both the primary antenna and the radio wave coupling portion of the secondary antenna, is In addition to not changing, it is possible to suppress a leakage magnetic flux that is a magnetic flux linked to only one of the primary antenna and the radio wave coupling portion of the secondary antenna. For this reason, it becomes possible to suppress the change of the coupling coefficient which is the ratio of the main magnetic flux and the leakage magnetic flux. Therefore, even if the displacement member deviates from the fully closed position, it is possible to obtain the required magnetic field strength in the secondary antenna.

  According to the present invention, in the short-range wireless communication system, even if the displacement member is not completely closed, the necessary magnetic field strength can be obtained.

1 is a block diagram showing a schematic configuration of a short-range wireless communication system. The perspective view which shows the structure of a primary antenna and a secondary antenna. FIG. 3 is an enlarged perspective view of FIG. 2 showing the positional relationship between the primary antenna and the radio wave coupling portion of the secondary antenna. The front view which shows the attachment position of the secondary antenna with respect to a door glass. The longitudinal cross-sectional view which shows the attachment position of the secondary antenna with respect to a door glass. The schematic diagram which shows the positional relationship of the primary antenna and secondary antenna by the movement of a primary antenna. The figure which shows the simulation result of the magnetic field strength by the position shift with a primary antenna and a secondary antenna. The figure which shows the equivalent circuit of a reader / writer, a secondary antenna, and a tag. The perspective view which shows the structure of a primary antenna and a secondary antenna. FIG. 10 is an enlarged perspective view of FIG. 9 showing the positional relationship between the primary antenna and the radio wave coupling portion of the secondary antenna. Schematic which shows the interlinkage magnetic flux of the radio coupling part of a primary antenna and a secondary antenna. The figure which shows the simulation result of the magnetic field strength by the position shift with a primary antenna and a secondary antenna. The enlarged perspective view which shows the positional relationship of the radio wave coupling part of a primary antenna and a secondary antenna.

(First embodiment)
A first embodiment in which the present invention is embodied in a short-range wireless communication system for a vehicle will be described below with reference to FIGS.

  As shown in FIG. 1, the vehicle 1 is provided with a mobile phone key system 3 that uses the mobile phone 2 as an electronic key by registering the ID code of the vehicle 1 in the mobile phone 2. For example, RFID (Radio Frequency IDentification) is used for the communication of the cellular phone key system 3 as near field communication (NFC). For example, FeliCa (registered trademark) or the like is used for the RFID. For example, HF (High Frequency) is used as the frequency of the RFID. The vehicle 1 corresponds to a communication target, and the mobile phone 2 corresponds to a communication terminal. The mobile phone key system 3 corresponds to a short-range wireless communication system.

  The mobile phone key system 3 executes ID (Identification) verification of the mobile phone 2 by “holding” the mobile phone 2 close to the vicinity of the vehicle 1. That is, when the mobile phone 2 receives the drive radio wave Sv from the vehicle 1 while holding the mobile phone 2 close to the vehicle 1, the mobile phone 2 returns an ID code signal Sid to the vehicle 1 with the drive radio wave Sv as a power source, and the ID The ID verification of the mobile phone 2 is performed by the ID code included in the code signal Sid, that is, the so-called holding verification. The drive radio wave Sv and the ID code signal Sid constitute a transmission / reception radio wave.

  The mobile phone key system 3 includes a door entry function that performs locking and unlocking of the door lock if the verification is established outside the vehicle, and a push-operated engine installed in the vehicle if the verification is established in the vehicle. There is a one-push engine start function in which the engine is started simply by pressing the switch 4. The engine switch 4 can perform not only engine start operation but also power supply transition operation of the vehicle 1.

  The vehicle 1 is provided with an ID verification device 5 that performs ID verification with the mobile phone 2, a door lock device 6 that manages the locking and unlocking of the door lock, and an engine starter 7 that manages the operation of the engine. These are connected via the in-vehicle bus 8. The ID verification device 5 is provided with a verification ECU (Electronic Control Unit) 9 as a control unit of the ID verification device 5. When the verification ECU 9 obtains an ID code from the mobile phone 2 by short-range wireless communication, the verification ECU 9 performs ID verification by comparing the ID code with its own.

  A vehicle outside reader / writer 10 capable of short-range wireless communication with the mobile phone 2 located outside the vehicle is provided near the door of the vehicle 1. The outside reader / writer 10 is a kind of communication device capable of transmitting and receiving radio waves by electromagnetic induction with a terminal such as a non-contact IC card. The main body 10a of the outside reader / writer 10 is provided with a communication circuit 11 that performs modulation of transmission radio waves, demodulation / amplification of reception radio waves, and the like. The outside reader / writer 10 constitutes a communication master.

  An antenna 12 of the outside reader / writer 10 is connected to the communication circuit 11. As the antenna 12, a kind of loop antenna of a magnetic field antenna in which a plurality of antenna wires (antenna elements) are wound in an annular shape is used. The antenna 12 includes a series resonance circuit including a coil 13 and a resonance capacitor 14. The antenna 12 is a transmission / reception antenna that can both transmit and receive radio waves.

  In the vehicle, for example, the center console is provided with an in-car reader / writer 15 capable of short-range wireless communication with the mobile phone 2 brought into the car. The in-car reader / writer 15 includes a communication circuit 16 and an antenna 17 like the in-car reader / writer 10, and the antenna 17 also includes a series resonance circuit of a coil 18 and a capacitor 19. These reader / writers 10 and 15 are capable of both transmission of the drive radio wave Sv and reception of various radio waves transmitted from the mobile phone 2, that is, mutual communication.

  On the other hand, the mobile phone 2 is provided with a terminal control unit 20 that controls various operations of the mobile phone 2. The mobile phone 2 is provided with a tag 21 that performs near field communication with the reader / writers 10 and 15. The tag 21 is provided with a communication control circuit 22 that manages the operation of the tag 21. In the communication control circuit 22, an ID code is registered so that the mobile phone 2 functions as a vehicle key.

  A transmission / reception antenna 23 is connected to the communication control circuit 22 as an antenna of the tag 21. As the transmission / reception antenna 23, a loop antenna which is a kind of magnetic field antenna is used. The transmission / reception antenna 23 includes a series resonance circuit including a coil 24 in which an antenna wire is wound in an annular shape and a resonance capacitor 25. The tag 21 is activated when the driving radio wave Sv is received from the reader / writers 10 and 15 by the short-range wireless communication, and the ID code signal Sid including the ID code registered in the tag 21 is transmitted via the short-range wireless communication. Reply to 15.

  The vehicle 1 is provided with a reader / writer ECU 26 that controls the operations of the reader / writers 10 and 15. The reader / writer ECU 26 intermittently transmits the drive radio wave Sv from the outside reader / writer 10 when the vehicle 1 is parked or stopped. When the reader / writer ECU 26 receives the ID code signal Sid from the tag 21 as a response to the drive radio wave Sv, the reader / writer ECU 26 transfers the ID code to the verification ECU 9. When the collation ECU 9 inputs the ID code from the reader / writer ECU 26, the collation ECU 9 collates the ID code and determines whether or not the mobile phone 2 is a regular communication partner.

  In the cellular phone key system 3, a secondary antenna 28 is attached to the door glass 27 of the vehicle 1, and the radio wave of the outside reader / writer 10 is relayed by the secondary antenna 28 to increase the communication area of the outside reader / writer 10. Secondary antenna relay type. In the case of this example, the effective distance of the reader / writer 10 outside the vehicle is increased by pulling out the communication distance of the reader / writer 10 outside the vehicle (cell phone 2 side) by the secondary antenna 28 and increasing the antenna area of the secondary antenna 28. Enlarge. Thereby, the communication area of the reader / writer 10 outside the vehicle is widened, and the communication feasibility of the collation is ensured. The door glass 27 corresponds to a displacement member.

  As shown in FIGS. 2 and 3, the secondary antenna 28 is provided with a sheet-like flexible substrate 29. The flexible substrate 29 is a substrate that can be freely bent and deformed. The antenna area of the radio wave coupling portion 35 of the secondary antenna 28 is formed to be larger than the antenna 12 of the outside reader / writer 10, that is, the primary antenna 12.

  In the case of the present embodiment, the secondary antenna 28 is formed with two annular antennas 31 and 32 and a pair of connection antennas 33 and 34 that connect them. The annular antennas 31 and 32 and the connection antennas 33 and 34 are formed as one antenna line.

  The secondary antenna 28 is formed as a radio wave coupling portion 35 on the first annular antenna 31 side of the pair of annular antennas 31 and 32. The radio wave coupling unit 35 is arranged so as to overlap the primary antenna 12 when the door glass 27 is fully closed. The radio wave coupling unit 35 is a part for electromagnetically coupling the secondary antenna 28 to the primary antenna 12.

  The secondary antenna 28 is formed as a radio wave input / output unit 36 on the second annular antenna 32 side of the pair of annular antennas 31 and 32. The radio wave input / output unit 36 is a place where the user holds the mobile phone 2 over the door glass 27 outside the vehicle.

  Since the radio wave coupling unit 35 and the radio wave input / output unit 36 are formed in the secondary antenna 28, the secondary antenna 28 is connected to the primary antenna 12 by the radio wave coupling unit 35, and communicates with the mobile phone 2 by the radio wave input / output unit 36. In addition, the secondary antenna 28 of this example operates to induce the same radio wave as that induced in one of the radio wave coupling unit 35 and the radio wave input / output unit 36 to the other side, thereby enabling radio wave relaying. It is possible.

  As shown in FIG. 1, a resonance capacitor 37 is connected to a part of the second annular antenna 32. Therefore, the secondary antenna 28 becomes a series resonance circuit of the coil 30 and the capacitor 37, and functions as an antenna by this series resonance circuit.

  As shown in FIGS. 4 and 5, the secondary antenna 28 of this example is attached to the inner surface of the door glass 27 of the rear seat door 38. The rear seat means a seat behind the driver seat and the passenger seat. The door glass 27 can be opened and closed by sliding in the vertical direction by operating a window opening / closing switch (not shown). The secondary antenna 28 is disposed on the rear surface of the door glass 27 at a position above the vehicle body and closer to the front.

  The outside reader / writer 10 is attached to the door edge of the vehicle body ceiling 1a. The secondary antenna 28 is arranged at a position that enters the communication area of the primary antenna 12 of the outside reader / writer 10 when the door glass 27 is in a fully closed state or a substantially fully closed state. For this reason, only a small area is formed for the communication area of the primary antenna 12 itself of the reader / writer 10 outside the vehicle, but radio waves are relayed by the secondary antenna 28 so that the communication area of the reader / writer 10 outside the vehicle is one of the door glass 27. Amplified in a wide area that fills the area.

  The secondary antenna 28 is a retrofitted sheet-like component in which a series resonance circuit (a coil 30 and a capacitor 31) is mounted on one flexible substrate 29. Therefore, when the secondary antenna 28 is not attached to the door glass 27 of the vehicle 1, the sheet-like secondary antenna 28 is aligned with the outside reader / writer 10 and attached to the back surface of the door glass 27. wear.

  As shown in FIGS. 3 and 6, when the door glass 27 is fully closed, the door glass 27 moves to the center of the radio wave coupling portion 35 of the secondary antenna 28 in the moving direction (displacement direction: X-axis direction). It arrange | positions so that the primary antenna 12 may be located. In addition, when closing the door glass 27, it may be possible to stop the closing operation before reaching the fully closed position, or to open the window somewhat intentionally, so that it is deviated from the fully closed position. However, it is desirable that the short-range wireless communication similar to that at the time of full-close is established even in a displacement range in which there is no problem regarding the full-close, that is, a so-called full-close allowable range.

  Therefore, in this embodiment, the main magnetic flux constant structure 40 is provided in which the main magnetic flux between the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 does not change. The main magnetic flux is a magnetic flux linked to both the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28. That is, the primary antenna 12 is included in the outer area A2 of the radio wave coupling portion 35 of the secondary antenna 28 in the fully closed permissible range in the moving direction (X-axis direction) of the door glass 27. Specifically, in the moving direction of the door glass 27 (X-axis direction), the length L2 of the radio wave coupling portion 35 of the secondary antenna 28 is formed sufficiently larger than the length L1 of the primary antenna 12. The lengths in the Y-axis direction of the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 are formed to be the same.

  Further, the opposed area A1 between the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 does not change in the fully closed permissible range in the moving direction (X-axis direction) of the door glass 27. Specifically, first, in a state where the door glass 27 is fully closed, the radio wave coupling portion 35 of the secondary antenna 28 is included in the outer area A2 of the primary antenna 12. Even if the door glass 27 is not fully closed within the fully closed allowable displacement range, the primary antenna 12 is included in the outer area A2 of the radio wave coupling portion 35 of the secondary antenna 28. Further, the facing area A1 between the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 does not change. Therefore, the main magnetic flux between the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 does not change, and the leakage magnetic flux does not change. The leakage magnetic flux is a magnetic flux interlinking with either the primary antenna 12 or the radio wave coupling portion 35 of the secondary antenna 28. Therefore, in the fully closed permissible range, the change in the coupling coefficient is suppressed, and the required magnetic field strength can be obtained in the radio wave input / output unit 36 of the secondary antenna 28.

  Now, when the vehicle 1 is parked (engine stopped, door lock locked), the outside reader / writer 10 uses the driving radio wave Sv at a polling period in order to investigate whether the mobile phone 2 exists around the vehicle. Send intermittently. Here, as shown in the equivalent circuit of FIG. 8, the primary antenna 12 and the secondary antenna 28 of the outside reader / writer 10 are coupled by electromagnetic induction, and the drive radio wave Sv of the primary antenna 12 is applied to the secondary antenna 28. Thus, it is transmitted over a wide range via the secondary antenna 28.

  In the case of this example, the communication distance of the primary antenna 12 is extended by the secondary antenna 28, so that the driving radio wave Sv of the primary antenna 12 flies farther. Further, since the antenna area of the radio wave input / output unit 36 of the secondary antenna 28 is formed larger than the antenna area of the primary antenna 12, the holding area of the mobile phone 2 is wider than when only the primary antenna 12 is provided. Therefore, the effective area of the holding operation is widened.

  Here, for example, when the driver gets on the vehicle, as shown by a two-dot chain line in FIG. 5, the driver holds the mobile phone 2 held by the driver over the secondary antenna 28 from outside the vehicle. At this time, as shown in the equivalent circuit of FIG. 8, the primary antenna 12 and the secondary antenna 28 establish communication by electromagnetic induction, and the secondary antenna 28 and the tag 21 establish communication by electromagnetic induction. Short-distance wireless communication between the outside reader / writer 10 and the tag 21 is established. Therefore, the tag 21 is activated by the driving radio wave Sv from the outside reader / writer 10 and returns an ID code signal Sid to the vehicle 1 as a response.

  When the tag 21 returns the ID code signal Sid, the outside reader / writer 10 receives the ID code signal Sid via the secondary antenna 28. When the outside reader / writer 10 receives the ID code signal Sid at the primary antenna 12, it transfers the ID code included in the ID code signal Sid to the verification ECU 9. When the verification ECU 9 verifies the ID code of the tag 21 and confirms that ID verification is established, the verification ECU 9 unlocks the door lock. The operation at the time of locking the door lock is basically the same as the unlocking operation of the door lock, and the details are omitted.

  Subsequently, FIG. 7 shows a characteristic graph of the distance on the Z axis and the magnetic field strength. FIG. 7 is a simulation result of the magnetic field strength and the distance from the secondary antenna 28 when the position of the radio wave coupling portion 35 of the secondary antenna 28 with respect to the primary antenna 12 is deviated from the fully closed position.

  As shown in FIG. 7, as the distance from the secondary antenna 28 in the Z-axis direction increases, the magnetic field strength in the Z-axis direction of the secondary antenna 28 at that position decreases. Even if the deviation D between the center of the primary antenna 12 and the center of the radio wave coupling portion 35 of the secondary antenna 28 is, for example, 0 mm to 8 mm, the magnetic field strength hardly changes. Therefore, it can be seen that the required magnetic field strength can be obtained at the radio wave input / output unit 36 of the secondary antenna 28.

  As described above, in this example, when the secondary antenna 28 is attached to the inner surface of the door glass 27 and the mobile phone 2 is held over the reader / writer 10 outside the vehicle, the reader / writer 10 and the mobile phone 2 are connected between the reader / writer 10 outside the vehicle and the mobile phone 2. The exchanged radio wave is relayed by the secondary antenna 28 and held outside the vehicle, and collation is executed. Therefore, the communication area of the outside reader / writer 10 can be pulled out to the mobile phone 2 side (user side) by the secondary antenna 28. In addition, since the secondary antenna 28 is attached to the door glass 27 that originally has a large area, the antenna area of the secondary antenna 28 can be increased without worrying about the arrangement space.

  By the way, when the outside reader / writer 10 is attached to the door edge of the vehicle body ceiling 1a, the door edge does not have a sufficient area. Therefore, the size of the outside reader / writer 10, that is, the antenna area of the primary antenna 12 may be increased. Even if it is impossible to improve communication establishment, this cannot be satisfied. However, if radio waves are relayed by the secondary antenna 28 as in this example, there is a limitation in the arrangement space of the reader / writer 10 outside the vehicle, and the antenna area of the reader / writer 10 outside the vehicle cannot be increased. Even so, the communication area of the reader / writer 10 outside the vehicle can be widened by the secondary antenna 28. Therefore, it is possible to ensure the communication feasibility of the hand-check.

  Further, in this example, the primary antenna 12 is included in the outer area A2 of the radio wave coupling unit 35 of the secondary antenna 28, and the primary antenna 12 and the radio wave coupling unit 35 of the secondary antenna 28 in the fully closed tolerance range. The main magnetic flux constant structure 40 is provided in which the facing area A1 does not change. For this reason, since the main magnetic flux and the leakage magnetic flux can be made constant regardless of the position of the door glass 27 in the fully closed permissible range, the coupling coefficient does not change. Therefore, the necessary magnetic field strength can be constantly obtained in the radio wave input / output unit 36 of the secondary antenna 28 in the vicinity of the fully closed door glass 27.

As described above, according to the embodiment described above, the following effects can be obtained.
(1) The shape of the secondary antenna 28 is a shape having a radio wave coupling unit 35 and a radio wave input / output unit 36, and the primary antenna 12 and the radio wave are in a fully closed tolerance between the primary antenna 12 and the secondary antenna 28. A main magnetic flux constant structure 40 that stabilizes the main magnetic flux with the coupling portion 35 is provided. For this reason, if the door glass 27 is located in the fully closed permissible range, the main magnetic flux does not change. Further, if the door glass 27 is positioned within the fully closed permissible range, the value of the main magnetic flux and the leakage magnetic flux does not change regardless of the position of the door glass 27. The coupling coefficient as a percentage does not change. Therefore, even if the door glass 27 is displaced from the fully closed position, it is possible to obtain a required magnetic field strength in the secondary antenna 28.

  (2) The main magnetic flux constant structure 40 in which the facing area A1 between the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 is not displaced in the fully closed permissible range. For this reason, the main magnetic flux can be stabilized only by changing the size of the radio wave coupling portion 35 of the secondary antenna 28.

  (3) Even if the position of the radio wave coupling portion 35 of the secondary antenna 28 is shifted in the fully closed allowable range, the primary antenna 12 is included in the outer area A2 of the radio wave coupling portion 35 of the secondary antenna 28. It can suppress that 12 enlarges. Therefore, exposure of the primary antenna 12 can be avoided as much as possible.

  (4) The secondary antenna 28 of the reader / writer 10 outside the vehicle is attached to the door glass 27, and radio waves are relayed by the secondary antenna 28, so that the mobile phone 2 and the reader / writer 10 outside the vehicle are collated. Therefore, even if the arrangement space of the outside reader / writer 10 is limited and the antenna area of the outside reader / writer 10 cannot be increased, the outside reader The communication area of the writer 10 can be widened. For this reason, since the admissibility of the holding position of the mobile phone 2 appears, it is possible to ensure the communication feasibility of the holding check.

(Second Embodiment)
Hereinafter, a second embodiment in which the present invention is embodied in a vehicle short-range wireless communication system will be described with reference to FIGS. 9 to 11. In the short-range wireless communication system of this embodiment, the primary antenna 12 is different from that of the first embodiment. Hereinafter, a description will be given focusing on differences from the first embodiment. Note that the short-range wireless communication system of this embodiment has the same configuration as the short-range wireless communication system of the first embodiment shown in FIG.

  As shown in FIGS. 9 and 10, conductive conductor plates 41 extending in the moving direction are installed on both side surfaces 12a and 12b in the X-axis direction, which is the moving direction of the door glass 27 of the primary antenna 12. ing. When the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 face each other, the conductor plates 41 are formed so that the antenna opening of the radio wave coupling portion 35 of the secondary antenna 28 that is not opposed to the primary antenna 12 is formed. cover.

  As shown in FIG. 11, when the longitudinal section of the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 is viewed, the leakage magnetic flux interlinking only the radio wave coupling portion 35 of the secondary antenna 28 is caused by the conductor plate 41. Absorbed. For this reason, the change of the leakage magnetic flux by the position of the electromagnetic wave coupling | bond part 35 of the secondary antenna 28 can be suppressed, and the change of a coupling coefficient can be suppressed.

  Next, FIG. 12 shows a characteristic graph of the distance on the Z axis and the magnetic field strength. FIG. 12 is a simulation result of the magnetic field intensity and the distance from the secondary antenna 28 when the position of the radio wave coupling portion 35 of the secondary antenna 28 with respect to the primary antenna 12 is deviated from the fully closed position.

  As shown in FIG. 12, as the distance from the secondary antenna 28 in the Z-axis direction increases, the magnetic field strength in the Z-axis direction of the secondary antenna 28 at that position decreases. Even if the deviation D between the center of the primary antenna 12 and the center of the radio wave coupling portion 35 of the secondary antenna 28 is, for example, 0 mm to 8 mm, the magnetic field strength is not substantially changed. Therefore, it can be seen that the required magnetic field strength can be obtained at the radio wave input / output unit 36 of the secondary antenna 28.

As described above, according to the embodiment described above, in addition to the functions and effects of (1), (2), and (4) of the first embodiment, the following functions and effects can be achieved.
(5) Since the conductor plates 41 are provided on both side surfaces 12a and 12b of the primary antenna 12 in the moving direction of the door glass 27, the main magnetic flux between the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 does not change. In addition, leakage flux between the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 can be suppressed. For this reason, the change of the coupling coefficient which is a ratio of the main magnetic flux and the leakage magnetic flux can be suppressed. Therefore, even if the door glass 27 is displaced from the fully closed position, the required magnetic field strength can be obtained in the secondary antenna 28.

In addition, the said embodiment can be implemented with the following forms which changed this suitably.
In the above embodiment, the primary antenna 12 and the radio wave coupling portion 35 of the secondary antenna 28 have the same length in the Y-axis direction, but the length of the primary antenna 12 is also 2 in the Y-axis direction. You may form smaller than the length of the electromagnetic wave coupling part 35 of the next antenna 28. FIG. In this way, if the primary antenna and the secondary antenna 28 are misaligned in the Y-axis direction, changes in the main magnetic flux due to the misalignment can be suppressed.

  In the second embodiment, there is a practically no gap between the primary antenna 12 and the conductor plate 41, but the gap may be eliminated. Further, the primary antenna 12 and the conductor plate 41 may be integrally formed.

-In the said 2nd Embodiment, although the conductor plate 41 was installed in the both sides | surfaces of the moving direction of the door glass 27, if the possibility of position shift is one, the conductor plate 41 may be installed only in one side. .
In the second embodiment, the conductor plate 41 may be installed not only in the moving direction but around the primary antenna 12.

  In the above configuration, the length L1 of the primary antenna 12 is set smaller than the length L2 of the radio wave coupling portion 35 of the secondary antenna 28 in the moving direction of the door glass 27. However, as shown in FIG. 13, the length L2 of the radio wave coupling portion 35 of the secondary antenna 28 may be set smaller than the length L1 of the primary antenna 12 in the moving direction of the door glass 27. It is desirable that the radio wave coupling unit 35 of the secondary antenna 28 is included in the outer area of the primary antenna 12 in the fully closed allowable range.

In the above-described embodiment, only the outside reader / writer 10 is not limited to the secondary antenna relay type, and may be applied to the in-vehicle reader / writer 15.
In the above embodiment, the in-vehicle reader / writer 15 may be omitted, and the primary antenna 12 of the out-of-vehicle reader / writer 10 may be used as it is as an in-vehicle reader / writer. According to such a configuration, a plurality of different communication areas can be formed by one outside reader / writer, so that it is not necessary to provide a separate communication master for each communication area. Therefore, the number of communication masters can be reduced.

In the above embodiment, the position where the secondary antenna 28 is attached to the door glass 27 is not limited to the position illustrated in the embodiment, and may be changed to another position.
In the above configuration, the secondary antenna 28 is not limited to a retrofitted component, and may be an antenna integrated into the door glass 27.

In the above configuration, a pattern, a character, or the like for notifying the holding position may be drawn on the place where the secondary antenna 28 is disposed on the glass surface of the door glass 27.
In the above configuration, the tag 21 is not limited to being an IC chip independent of the terminal control unit 20, and the function of the tag 21 may be incorporated in the terminal control unit 20.

  In the above configuration, the secondary antenna 28 is not limited to the coil 30 and the capacitor 37 both being provided on the door glass 27. For example, only the coil 30 may be provided on the door glass 27 and the capacitor 37 may be provided on the vehicle body ceiling 1a.

In the above configuration, the arrangement position of the outside reader / writer 10 is not limited to the vehicle body ceiling 1a, and may be another member such as a door trim or a pillar.
In the above configuration, the secondary antenna 28 is not limited to a single sheet-like component, and may be an unfoldable antenna using a plate-like substrate, for example.

-In the said embodiment, a displacement member is not limited to the door glass 27, You may employ | adopt another movable member.
In the above embodiment, the radio wave coupling unit 35 and the radio wave input / output unit 36 are not limited to a square shape, and may be a circular shape, for example. Further, the radio wave coupling unit 35 and the radio wave input / output unit 36 may have shapes having the same area.

In the above configuration, the communication target is not limited to the vehicle 1 and may be anything as long as it performs wireless communication with a communication terminal.
In the above configuration, the communication terminal is not limited to the mobile phone 2 and may be any terminal that can transmit the ID code wirelessly.

In the above embodiment, short-range wireless communication is not limited to RFID, and other communication methods can be employed.
In the above embodiment, the transmission / reception radio wave is not limited to the drive radio wave Sv and the ID code signal Sid, and various radio waves according to the communication format can be adopted.

  In the above configuration, each antenna (secondary antenna 28) of the mobile phone key system 3 is not limited to a loop antenna, and other antennas such as a dipole antenna can also be used.

  In the above embodiment, the frequency of the mobile phone key system 3 is not limited to HF, and for example, LF (Low Frequency), UHF (Ultra High Frequency), or the like may be used. Further, the frequency of the radio wave may be different between the two-way communication going and returning.

  -The technical idea of this example is not limited to being applied to the vehicle 1, but can be applied to other devices and apparatuses.

  DESCRIPTION OF SYMBOLS 1 ... Vehicle as communication object, 2 ... Mobile phone as communication terminal, 10 ... Outside reader / writer as communication master, 12 ... Primary antenna, 15 ... In-car reader / writer, 17 ... Antenna, 23 ... Transmission / reception antenna, 26 ... Reader / writer ECU, 27 ... Door glass as displacement member, 28 ... Secondary antenna, 31 ... First annular antenna, 32 ... Second annular antenna, 33, 34 ... Connection antenna, 35 ... Radio wave coupling unit, 36 ... Radio wave input Output part 38 ... Rear seat door 40 ... Main magnetic flux constant structure 41 ... Conductor plate A1 ... Opposite area (outside area), A2 ... Outer area, D ... Deviation, L1, L2 ... Length, Sid ... ID code Signal, Sv: Driving radio wave.

Claims (5)

A communication master provided in a communication target and its communication terminal can communicate with each other by short-range wireless communication, and a secondary antenna capable of relaying transmission / reception radio waves from a primary antenna provided in the communication target to the communication terminal. A short-range wireless communication system provided on a displacement member mounted on the communication target, wherein the communication terminal and the primary antenna can execute the short-range wireless communication via the secondary antenna,
The secondary antenna has a shape having an annular antenna on both sides thereof by narrowing the middle of one annular antenna line, and one of these is used as a radio wave coupling portion with the primary antenna, and the other of these Is used as a radio wave input / output unit to relay the transmission / reception radio wave of the primary antenna,
Assuming that the movement direction range of the displacement member, which can be regarded as the closed state of the displacement member, is a fully-closed allowable range, if the displacement member is located in the fully-closed allowable range, where the displacement member is located. A short-range wireless communication system comprising a main magnetic flux constant structure that makes the main magnetic flux between the primary antenna and the radio wave coupling portion of the secondary antenna constant even if there is. The short-range wireless communication system according to claim 1,
The main magnetic flux constant structure is a structure in which a facing area between the primary antenna and the radio wave coupling portion of the secondary antenna does not change in a fully closed permissible range in the moving direction of the displacement member. Distance wireless communication system. The short-range wireless communication system according to claim 1 or 2,
The main magnetic flux constant structure is a structure in which the radio wave coupling portion of the secondary antenna is included in the outer area of the primary antenna in a fully-closed allowable range in the moving direction of the displacement member. Wireless communication system. The short-range wireless communication system according to claim 1 or 2,
The main magnetic flux constant structure is a structure in which the primary antenna is included in an outer area of the radio wave coupling portion of the secondary antenna in a fully closed permissible range in the moving direction of the displacement member. Wireless communication system. The short-range wireless communication system according to claim 4,
A short-distance wireless communication system, wherein conductive conductor plates are provided on at least both sides of the primary antenna in the moving direction of the displacement member.

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