JP5206328B2 - Electronic key system - Google Patents

Description

  The present invention relates to an electronic key system that controls a vehicle in accordance with a result of code verification using wireless communication between a portable device carried by a user and a vehicle-side device mounted on the vehicle.

Conventionally, as an electronic key system of this type, for example, a technique described in Patent Document 1 is known. In the technique described in this document, the portable device includes a receiving unit for receiving a request signal transmitted from the vehicle-side device, a reception sensitivity switching switch for manually switching the reception sensitivity of the receiving unit, and the like. For example, when it is considered that code verification cannot be performed due to the influence of noise from home appliances, the request sensitivity of the request signal is changed while the reception sensitivity of the reception unit is switched to low sensitivity by manual operation of the reception sensitivity changeover switch. Make the mobile device physically close to the sender. In this way, an attempt is made to increase the probability that code verification is possible even under the influence of noise.
JP 2006-306161 A

  By the way, if the portable device is placed in a situation where it receives noise, the built-in battery may be consumed in a short time even though it is not used.

  Specifically, when the portable device is placed in a situation where it receives noise, the portable device is configured, for example, by determining whether or not the noise received by the receiving antenna is a request signal transmitted from the vehicle-side device. The receiver is activated and current consumption increases. In addition, the receiving unit constituting the portable device may mistakenly recognize the noise received by the receiving antenna as a request signal transmitted from the vehicle-side device. In this case, the control constituting the portable device The unit is activated and transmits an ID signal including an ID code from the transmitting antenna. This further increases current consumption. By repeating such an operation, the built-in battery is consumed in a short period of time even though it is not used. In the above prior art, the user cannot determine whether or not the portable device is placed in a situation where it receives noise.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide an electronic key system capable of reducing the current consumption of the built-in battery.

In order to achieve such an object, according to the first aspect of the present invention, according to a result of code verification using wireless communication between a portable device carried by a user and a vehicle-side device mounted on the vehicle, An electronic key system for controlling a vehicle, wherein the portable device is received by a portable device receiving antenna for wirelessly receiving a signal transmitted from the vehicle device and the portable device receiving antenna. A portable device side receiver that determines whether or not the signal to be detected is noise, and determines a voltage level of the noise based on being determined to be noise, and the noise determined by the portable device side receiver a portable device noise level display unit for displaying the voltage level of, based on the predetermined noise detection instruction operation is determined to have been made, usually mode the operating mode of the portable device-side reception unit An operation mode switching unit for switching from a door to a noise detection mode, a locking switch for locking the vehicle door, and an unlocking switch for unlocking the vehicle door, and the noise detection instruction operation includes: Unlike the locking operation using the locking switch and the unlocking operation using the unlocking switch, and the predetermined operation using the locking switch and the unlocking switch, the operation mode of the portable device side receiving unit is when the noise detection mode only, the portable device receiving unit determines a voltage level of the noise, the portable device noise level display unit is characterized that you display the voltage level of the noise.
According to a second aspect of the present invention, the vehicle is controlled according to a result of code verification using wireless communication between a portable device carried by the user and a vehicle side device mounted on the vehicle. An electronic key system, wherein the portable device is a portable device-side receiving antenna for wirelessly receiving a signal transmitted from the vehicle-side device, and a signal received by the portable device-side receiving antenna is noise. Based on determining whether or not a predetermined noise detection instruction operation has been performed, and determining whether or not there is a mobile device side receiving unit that determines the voltage level of noise based on being determined to be noise An operation mode switching unit that switches the operation mode of the portable device side receiving unit from a normal mode to a noise detection mode, a portable device operation mode display unit that displays the operation mode of the portable device, A portable device-side noise level display unit that displays a voltage level of noise determined by the portable device-side receiver, and the portable device only when the operation mode of the portable device-side receiver is a noise detection mode. The side receiving unit determines a voltage level of noise, and the portable device side noise level display unit displays the voltage level of noise.

  In such a configuration as an electronic key system, first, it is determined by the portable device-side receiving unit whether or not the signal received by the portable device-side receiving antenna is noise, and is determined to be noise. The voltage level of noise is determined based on And the voltage level of the noise judged by the portable device side receiving part is displayed on the portable device side noise level display part. Thereby, the user can confirm the noise reception status of the portable device. Therefore, when the user confirms that the portable device receives a lot of noise, the portable device can be prevented from being stored in a noisy environment, for example, by changing the storage location of the portable device. . Therefore, the current consumption of the built-in battery can be reduced.

In addition , the user can check the voltage level of noise by performing a noise detection instruction operation at the storage location of the portable device. Further, since the voltage level of noise is displayed only in the noise detection mode, the current consumption of the built-in battery can be further reduced.

Moreover, according to the structure of the said Claim 1 , since it is not necessary to provide a switch only for a portable device side, it does not invite the enlargement of the physique of a portable device. Further, according to the configuration of the second aspect, the user can check the operation mode.

Moreover, in the configuration according to claim 1 or 2 , in the invention according to claim 3 , the operation mode switching unit operates the portable device side receiving unit based on the fact that a predetermined release condition is satisfied. The mode is switched from the noise detection mode to the normal mode. Thereby, when the release condition is satisfied, the portable device is switched to the normal mode.

In the configuration according to claim 3 , as in the invention according to claim 4 , the portable device further includes a timing unit that counts an elapsed time since switching to the noise detection mode, It is desirable that the cancellation condition includes that the time counted by the timing unit has elapsed for a certain time. As a result, the normal mode is automatically entered when a certain period of time has elapsed since switching to the noise detection mode.

Moreover, the display mode which displays the voltage level of noise by the said portable device side noise level display part is arbitrary. For example, a monitor screen may be adopted as the portable device-side noise level display unit and displayed as text or an image. In addition, as in the invention described in claim 5 , the portable device-side noise level display unit includes a light emitting element, and turns on and off the light emitting element in a pattern according to the voltage level of the noise. It is good as well. In addition, the pattern which makes this light emitting element turn on / off is also arbitrary, For example, you may make a lighting / lighting interval short, so that the voltage level of noise is large.

(First embodiment)
A first embodiment of an electronic key system according to the present invention will be described below with reference to FIGS.

  The electronic key system controls a vehicle according to a result of code verification using wireless communication between a portable device 1 (see FIG. 1) carried by a user and a vehicle side device (not shown) mounted on the vehicle. It is a system that performs. In the present embodiment, the electronic key system is embodied as a so-called smart entry and start system that locks and unlocks a vehicle door and starts an in-vehicle engine, for example.

  In the electronic key system in which the portable device 1 is used, when the user approaches the vehicle door while carrying the portable device 1, the vehicle-side device transmits a request signal, and the portable device 1 that has received the request signal stores and holds the request signal in advance. An ID signal including the self ID code is transmitted. On the other hand, when the vehicle-side device receives this ID signal from the portable device 1, the vehicle-side device compares this ID code with the vehicle-specific ID code, confirms that both match, and the user touches the knob on the vehicle door. As a condition, the vehicle door is unlocked. Further, when the user carrying the portable device 1 presses the lock switch from the outside of the vehicle, the lock is performed under the condition that the ID codes match. For this reason, the user who carries the portable device 1 can lock and unlock the vehicle door without operating the portable device 1. In the present embodiment, an LF (low frequency) signal is used as the request signal, and the frequency of the LF signal is, for example, “approximately 134 [kHz]”. Further, an RF (radio frequency) signal is adopted as the ID signal.

  Hereinafter, a description will be given with reference to FIG. FIG. 1 is a block diagram showing the configuration of the portable device 1 of the electronic key system according to the present embodiment.

  As shown in FIG. 1, the portable device 1 includes an X-axis antenna 10a, a Y-axis antenna 10b, a Z-axis antenna 10c, variable capacitors 11a to 11c, a reception unit 12, a control unit 13, an RF transmission unit 20, and the like. .

  Among these, the X-axis antenna 10a, the Y-axis antenna 10b, and the Z-axis antenna 10c are antennas for wirelessly receiving a request signal transmitted from a vehicle side device (not shown). These X-axis antenna 10a, Y-axis antenna 10b, and Z-axis antenna 10c are provided with respect to the three-axis directions so as to receive radio waves from all directions. The X-axis antenna 10a, the Y-axis antenna 10b, and the Z-axis antenna 10c transmit the received signals to the receiving unit 12 when receiving signals. The X-axis antenna 10a, the Y-axis antenna 10b, and the Z-axis antenna 10c correspond to the portable device-side receiving antenna described in the claims.

  The variable capacitors 11a to 11c are capacitors for finely adjusting the reception bands of the X-axis antenna 10a, the Y-axis antenna 10b, and the Z-axis antenna 10c. Specifically, the variable capacitor 11a is connected in parallel with the X-axis antenna 10a, the variable capacitor 11b is connected in parallel with the Y-axis antenna 10b, and the variable capacitor 11c is connected in parallel with the Z-axis antenna 10c. . The variable capacitors 11a to 11c are connected to the receiving unit 12, respectively. And it is possible to change the capacity | capacitance of the variable capacitors 11a-11c by outputting a signal from the receiving part 12, and changing the capacity | capacitance of X-axis antenna 10a, Y-axis antenna 10b, and Z-axis antenna 10c. Each resonance frequency can be changed. Note that a variable capacitance diode may be used instead of the variable capacitors 11a to 11c, and the capacitance is fixed unless it is necessary to finely adjust the reception bands of the X axis antenna 10a, the Y axis antenna 10b, and the Z axis antenna 10c. A capacitor may be used.

  The receiving unit 12 has a normal mode and a noise detection mode as operation modes, and normally operates in the normal mode. However, when receiving a signal indicating that the noise detection instruction operation has been performed from the control unit 13, the reception unit 12 switches the operation mode from the normal mode to the noise detection mode. In addition, when the signal indicating that the release condition is satisfied is received from the control unit 13, the receiving unit 12 switches the operation mode from the noise detection mode to the normal mode. These noise detection instruction operations, release conditions, etc. will be described later.

  When the operation mode is the normal mode, the reception unit 12 is received by the X-axis antenna 10a, the Y-axis antenna 10b, and the Z-axis antenna 10c (hereinafter collectively referred to as the portable device-side reception antenna 10). It is determined whether the received signal is a regular request signal transmitted from the vehicle side device or noise. Specifically, a regular request signal transmitted from the vehicle-side device includes a predetermined ID code, but noise generated from home appliances does not include such a predetermined ID code. Therefore, the receiving unit 12 performs signal processing (for example, A / D conversion) on the signal received by the portable device-side receiving antenna 10, and when the signal processing signal includes a predetermined ID code. While it is determined that the request signal is a legitimate request signal transmitted from the vehicle-side device, it is determined as noise when the predetermined ID code is not included. When the receiving unit 12 determines that the signal received by the portable device-side receiving antenna 10 is a normal request signal, the receiving unit 12 transmits a wake-up signal to the control unit 13 as indicated by an arrow A in FIG. To do. In addition, when the reception unit 12 determines that the signal received by the portable device-side reception antenna 10 is noise, the reception unit 12 does not transmit a wakeup signal to the control unit 13.

  When the operation mode is the noise detection mode, the reception unit 12 determines whether the signal received by the portable device-side reception antenna 10 is a regular request signal or noise, and determines that the signal is noise. Then, the voltage level of this noise is determined. The receiving unit 12 transmits a wake-up signal to the control unit 13 as indicated by an arrow A in FIG. 1, and a noise voltage to the control unit 13 as indicated by an arrow B in FIG. Send data indicating the level. Thus, the receiving unit 12 corresponds to the portable device-side receiving unit described in the claims.

  The receiving unit 12 includes a transponder function unit 12a. For example, when the electronic key system does not work well, for example, when the built-in battery 15 is exhausted, a magnetic field is formed around the engine switch by holding the portable device 1 over an engine switch (not shown) provided in the vehicle side device. Is done. Then, the transponder function unit 12a can transmit an ID code by an RF transmission unit 20 described later, and collation is performed. Since the transponder function unit 12a is publicly known, further detailed explanation is omitted here.

  The control unit 13 is configured as a normal computer having a well-known CPU, a memory such as a ROM, a RAM, and an EEPROM, an I / O, and a bus line (none of which is shown) for connecting them. The battery 14 is connected to a built-in battery 15, a lock button (locking switch) 16, an unlock button (unlocking switch) 17, a luggage button 18, an LED (light emitting element) 19, an RF transmitter 20, and the like. The EEPROM included in the control unit 13 stores and holds a unique ID code, various control programs, and the like.

  The control unit 13 is a luggage button for unlocking the trunk of the vehicle when the lock button 16 for locking the vehicle door is operated, or when the unlock button 17 for unlocking the vehicle door is operated. When 18 is operated, or when a wake-up signal (see arrow A) transmitted from the receiving unit 12 is received, power is supplied from the built-in battery 15 to start up. Incidentally, in the present embodiment, for example, a lithium coin battery is adopted as the built-in battery 15. The built-in battery 15 supplies power not only to the control unit 13 but also to the reception unit 12, the LED 19, the RF transmission unit 20, and the like. Further, the oscillator 14 starts to vibrate at a predetermined frequency when the control unit 13 is activated, and forms a clock. The control unit 13 executes various control processes in synchronization with the clock formed by the oscillator 14.

  Hereinafter, various control processes executed by the control unit 13 will be described. When a locking operation using the lock button 16 (for example, pressing once for a short time) is performed by the user, the control unit 13 is activated. After the activation, the control unit 13 generates data for locking the vehicle door and transmits the generated data to the RF transmission unit 20 described later (so-called wireless door lock function). Further, when an unlocking operation using the unlock button 17 (for example, pressing once for a short time) is performed by the user, the control unit 13 is activated. After the activation, the control unit 13 generates data to unlock the vehicle door and transmits the generated data to the RF transmission unit 20 (so-called wireless door unlock function). When a predetermined operation using the luggage button 18 (for example, pressing once for a short time) is performed by the user, the control unit 13 is activated. After the activation, the control unit 13 generates data indicating that the vehicle trunk is unlocked and opened, and transmits the generated data to the RF transmission unit 20 (so-called luggage door open function).

  Further, when determining that the noise detection instruction operation has been performed, the control unit 13 switches the operation mode of the reception unit 12 from the normal mode to the noise detection mode. Specifically, the control unit 13 determines whether or not a special operation using the lock button 16 and the unlock button 17 is performed by the user as the noise detection instruction operation. The special operation is optional as long as it is different from the locking operation using the lock button 16 and the unlocking operation using the unlock button 17. When determining that the noise detection instruction operation has been performed, the control unit 13 transmits a signal indicating that the noise detection instruction operation has been performed to the reception unit 12 as indicated by an arrow C in FIG. When receiving this signal, the receiving unit 12 switches the operation mode from the normal mode to the noise detection mode.

  Further, when determining that the release condition is satisfied, the control unit 13 switches the operation mode of the reception unit 12 from the noise detection mode to the normal mode. Specifically, the control unit 13 determines whether or not the special operation using the lock button 16 and the unlock button 17 is performed again by the user as the release condition. The special operation is optional as long as it is different from the locking operation using the lock button 16 and the unlocking operation using the unlock button 17. If it is determined that the release condition is satisfied, the control unit 13 transmits a signal indicating that the release condition is satisfied to the receiving unit 12 as indicated by an arrow D in FIG. When receiving this signal, the receiving unit 12 switches the operation mode from the noise detection mode to the normal mode. Thus, the control unit 13 corresponds to the operation mode switching unit described in the claims.

  Further, the control unit 13 turns on and off the LED 19 in a pattern corresponding to the voltage level of noise. Hereinafter, a description will be given with reference to FIGS. FIG. 2 is a diagram showing an example of a correspondence map between the voltage level of noise and the lighting interval of the LED 19, and FIG. 3 shows points of the LED 19 when the noise voltage level is, for example, “105 [dBμV / m]”. It is a timing chart which shows an example of a light extinction mode. Incidentally, the correspondence map M1 shown in FIG. 2 is stored and held in the EEPROM included in the control unit 13.

  As described above, the receiving unit 12 transmits data indicating the voltage level of noise to the control unit 13 (see arrow B in FIG. 1). When this data is received, the control unit 13 determines the lighting interval of the LED 19 with reference to the map M1. Specifically, when the voltage level of noise is, for example, “105 [dBμV / m]”, the control unit 13 sets the lighting interval to “2 [times / second]” (see FIG. 2). And the control part 13 lights LED19 twice in 1 second, for example in the aspect shown in FIG. Specifically, the control unit 13 first turns on the LED 19 for “0.1 [second]” and then turns off the LED 19 for “0.4 [second]”. The LED 19 is turned on again for “0.1 [second]”, and then the LED 19 is turned off for “0.4 [second]”.

  In the present embodiment, when the noise voltage level is, for example, “100 [dBμV / m]” or less, it is determined that the noise voltage level is weak, and the control unit 13 does not light the LED 19. . In the present embodiment, the number of times the LED 19 is turned on per second increases as the noise voltage level increases. However, the number of times the LED 19 lights up per second decreases as the noise voltage level increases. Good. In short, the control part 13 should just light up LED19 by the pattern according to the voltage level of noise.

  As shown in FIG. 1, the RF transmitter 20 is connected to an oscillator 21 and a portable device-side transmitting antenna 22. Similarly to the oscillator 14, the oscillator 21 also vibrates at a predetermined frequency to form a clock. Then, the RF transmitter 20 synchronizes with the clock formed by the oscillator 21 and transmits data transmitted from the controller 13 (for example, data indicating that the vehicle door is locked, information indicating that the vehicle door is unlocked). Data, data for unlocking the trunk and opening the door, etc.) are converted into RF signals, and the portable device-side transmitting antenna 22 is transmitted. The portable device-side transmission antenna 22 wirelessly transmits the RF signal transmitted from the RF transmission unit 20.

  The operation of the portable device 1 configuring the electronic key system configured as described above will be described with reference to FIG. FIG. 4 is a flowchart showing a processing procedure of noise level display processing executed by the portable device 1.

  At the start of the noise level display process S1, it is assumed that the receiving unit 12 is operating in the normal mode (the process of step S10). When the receiving unit 12 is operating in the normal mode, when the request signal is received from the vehicle-side device by the portable device-side receiving antenna 10, the control unit 13 is activated by receiving the wake-up signal from the receiving unit 12. Alternatively, when any one of the lock button 16, the unlock button 17 and the luggage button 18 is operated and a signal is input, the control unit 13 is activated.

  After the activation, the control unit 13 determines whether or not a noise detection instruction operation has been performed as the subsequent process of step S11. Specifically, the control unit 13 determines whether a special operation using the lock button 16 and the unlock button 17 has been performed by the user. Here, when it is determined that the special operation is not performed (“No” in the determination process of step S11), the control unit 13 executes the determination process of step S11 again. On the other hand, when it is determined that a special operation has been performed (“Yes” in the determination process of step S11), the control unit 13 proceeds to the subsequent process of step S20. In other words, the control unit 13 waits until it is determined that a special operation has been performed by repeatedly executing the determination process of step S11.

  If it is determined that a special operation has been performed, the control unit 13 switches the operation mode of the reception unit 12 to the noise detection mode as the processing of the subsequent step S20, and whether the release condition is satisfied as the determination processing of the subsequent step S21. Judge whether or not. Specifically, the control unit 13 determines whether or not the special operation has been performed again by the user. If it is determined that the special operation has been performed again (“Yes” in the determination process in step S21), the control unit 13 switches the operation mode of the reception unit 12 to the normal mode as the process in step S10. The determination process in subsequent step S11 is repeatedly executed.

  On the other hand, when it is not determined that the special operation has been performed again ("No" in the determination process in step S21), the reception unit 12 receives noise at the portable device-side reception antenna 10 as the determination process in step S22. Determine whether or not.

  If it is determined that no noise is received (“No” in the determination process in step S22), the control unit 13 executes the determination process in step S21 again. On the other hand, when determining that noise has been received (“Yes” in the determination process in step S22), the reception unit 12 converts the voltage level of the noise into data as the determination process in subsequent step S23. Specifically, the receiving unit 12 generates data indicating the voltage level of noise received by the portable device-side receiving antenna 10 by performing A / D conversion, for example. When this data is generated, the receiving unit 12 transmits the generated data to the control unit 13 as the process of subsequent step S24. Then, as the process of step S25, the control unit 13 turns on and off the LED 19 according to the received data, and again executes the determination process of the previous step S21.

  In the first embodiment described above, the receiving unit 12 determines whether or not the signal received by the portable device-side receiving antenna 10 is noise. Determine the voltage level. And the control part 13 decided to light-extinguish LED19 by the pattern according to the voltage level of the judged noise. As a result, the user can check the noise reception status of the portable device 1, so when the user confirms that the portable device 1 is receiving a lot of noise, for example, the storage location of the portable device is changed. For example, the portable device 1 can be prevented from being stored in a noisy environment. Therefore, the current consumption of the built-in battery 15 can be reduced.

In the first embodiment, the control unit 13 determines whether or not a special operation using the lock button 16 and the unlock button 17 is performed as the noise detection instruction operation, and the noise detection instruction operation is performed. When it is determined that the operation has been performed, the operation mode of the reception unit 12 is switched from the normal mode to the noise detection mode. The receiving unit 12 determines the noise voltage level only in the noise detection mode, and the control unit 13 turns on and off the LED 19 in a pattern according to the determined noise voltage level. did. As a result, the LED 19 is turned on and off only when the receiving unit 12 is in the noise detection mode, so that the current consumption of the built-in battery can be further reduced.
(Second Embodiment)
Hereinafter, a second embodiment of an electronic key system according to the present invention will be described with reference to FIG. FIG. 5 is a diagram corresponding to FIG. 1, and is a block diagram showing the configuration of the second embodiment of the portable device 1a of the electronic key system according to the present invention. As shown in FIG. 5, since the second embodiment has a configuration according to the first embodiment (FIG. 1), the description overlapping with that of the first embodiment is omitted. .

  The receiving unit 32 determines whether or not the LF radio wave received by the portable device-side receiving antenna 10 is a regular request signal transmitted from the vehicle-side device. If it is determined that the request signal is a legitimate request signal, the receiving unit 32 transmits a wake-up signal to the control unit 33 as shown by an arrow E in FIG. On the other hand, if it is determined that the request signal is not a legitimate request signal, the receiving unit 32 outputs the intensity (RSSI) of the LF radio wave and its data to the control unit 33 as indicated by an arrow F in FIG.

  When the lock button 16 is operated, the unlock button 17 is operated, the luggage button 18 is operated, or the wake-up signal transmitted from the receiving unit 32 (see arrow E) ) Is received, etc., and power is supplied from the built-in battery 15 to start up.

  The control unit 33 has a normal mode and a noise detection mode as operation modes. When the control unit 33 is activated as described above, it first operates in the normal mode. When the control unit 33 determines that the noise detection instruction operation is performed during the operation in the normal mode, the operation mode is changed from the normal mode to the noise mode. Switch to detection mode. On the other hand, when the control unit 33 determines that the release condition is satisfied during operation in the noise detection mode, the control unit 33 switches the operation mode from the noise detection mode to the normal mode.

  Of course, if the control unit 33 is not activated, the control unit 33 cannot receive the LF radio wave intensity and data from the reception unit 32 and cannot receive it. Only in some cases, the intensity and data of the LF radio wave are received from the receiving unit 32. When receiving the intensity and data of the LF radio wave, the control unit 33 refers to the map M1 to determine the lighting interval of the LED 19 and turns the LED 19 on and off.

  The operation of the portable device 1a configuring the electronic key system configured as described above will be described with reference to FIG. FIG. 6 is a flowchart showing a processing procedure of noise level display processing executed by the portable device 1a.

  At the start of the noise level display process S3, it is assumed that the control unit 33 is operating in the normal mode (step S30). During the operation in the normal mode, the control unit 33 determines whether or not a noise detection instruction operation has been performed as a process of subsequent step S31. Specifically, the control unit 33 determines whether a special operation using the lock button 16 and the unlock button 17 has been performed by the user. Here, when it is determined that the special operation is not performed (“No” in the determination process of step S31), the control unit 33 executes the determination process of step S31 again. On the other hand, when it is determined that a special operation has been performed (“Yes” in the determination process of step S31), the control unit 33 proceeds to the subsequent process of step S30. In other words, the control unit 33 waits until it is determined that a special operation has been performed by repeatedly executing the determination process of step S31.

  If it is determined that a special operation has been performed, the control unit 33 switches the operation mode to the noise detection mode as the processing of the subsequent step S40, and determines whether the release condition is satisfied as the determination processing of the subsequent step S41. To do. Specifically, the control unit 33 determines whether or not the special operation has been performed again by the user. If it is determined that the special operation has been performed again ("Yes" in the determination process of step S31), the control unit 33 switches the operation mode to the normal mode as the process of step S30, and then continues to step S31. Repeat the determination process.

  On the other hand, when it is not determined that the special operation has been performed again ("No" in the determination process in step S41), the control unit 33 obtains the intensity of the LF radio wave and the data from the reception unit 32 as the determination process in step S42. It is determined whether or not it has been received.

  If it is determined that the intensity of the LF radio wave and the data have not been received (“No” in the determination process in step S42), the control unit 33 executes the determination process in step S41 again. On the other hand, when determining that the intensity of the LF radio wave and the data thereof have been received (“Yes” in the determination process of step S42), the control unit 33 performs the process of the subsequent step S43 according to the intensity of the LF radio wave and the data thereof. The LED 19 is turned on and off, and the determination process of the previous step S41 is executed again.

In the second embodiment described above, the receiving unit 32 determines whether or not the LF radio wave received by the portable device-side receiving antenna 10 is a regular request signal, and is not a regular request signal. If it discriminate | determines, the intensity | strength (RSSI) of this LF radio wave and its data will be output with respect to the control part 33. FIG. When the control unit 13 receives the intensity and data of the LF radio wave during operation in the noise detection mode, the control unit 13 turns on and off the LED 19 with a pattern according to the data. As a result, the user can check the noise reception status of the portable device 1, so when the user confirms that the portable device 1 a is receiving a lot of noise, for example, the storage location of the portable device is changed. For example, the portable device 1 can be prevented from being stored in a noisy environment. Therefore, the current consumption of the built-in battery 15 can be reduced.
(Other embodiments)
The electronic key system according to the present invention is not limited to the configurations exemplified in the above embodiments, and can be implemented with various modifications without departing from the spirit of the present invention. is there. That is, for example, the following embodiments can be implemented by appropriately changing the above embodiments.

  In the first embodiment, the control unit 13 turns the LED 19 on and off with a pattern corresponding to the voltage level of noise. However, the display content is not limited to this. In addition to the noise voltage level, the operation mode of the receiving unit 12 set by the control unit 13 may be displayed on the LED 19. As a result, the user can check the operation mode. In this case, the portable device-side noise level display unit also serves as the portable device-side operation mode display unit, and the LED 19 is turned on and off with a special pattern different from the pattern corresponding to the noise voltage level. It is desirable to display the operation mode with. Moreover, it is good also as providing the portable machine 1 with LED as a portable device side operation mode display part separately from LED as a portable machine side noise level display part. Furthermore, a monitor screen may be adopted as the portable device-side operation mode display unit, and the control unit 13 may display the operation mode of the reception unit 12 with text, images, or the like. If the user can confirm the operation mode of the portable device 1 (specifically, the receiving unit 12), the display mode is arbitrary.

  In each of the above embodiments, the LED 19 is used as the portable device-side noise level display unit, and the control unit 13 or 33 turns off the LED 19 in a pattern according to the noise voltage level. Not limited to. In addition, for example, a monitor screen may be adopted as the portable device-side noise level display unit, and the control unit 13 or 33 may display the voltage level of noise as text or an image. If the user can confirm the noise reception status of the portable device 1 or 1a, the display mode is arbitrary.

  In each of the above embodiments (including modifications), the control unit 13 or 33 employs the same special operation as the noise detection instruction operation as the release condition, but is not limited thereto. The portable device 1 or 1a further includes a known counter circuit that measures the elapsed time since switching to the noise detection mode, and adopts that the time counted by the counter circuit elapses as a predetermined time as the release condition. Also good. As a result, the operation mode of the receiving unit 12 or the operation mode of the control unit 33 is automatically switched to the normal mode. However, it is only necessary to switch from the noise detection mode to the normal mode, and the release condition is arbitrary.

  Further, in each of the above embodiments (including modifications), the control unit 13 or 33 adopts that a special operation using the lock button 16 and the unlock button 17 is performed as the noise detection instruction operation. However, it is not limited to this. In addition, for example, a dedicated switch for switching to the noise detection mode may be provided in the portable device 1 or 1a, and the operation of the dedicated switch on the portable device side may be employed as the noise detection instruction operation. Alternatively, a dedicated switch for instructing switching to the noise detection mode may be provided in the vehicle side device, and operating this vehicle side dedicated switch may be employed as the noise detection instruction operation. In this case, when a noise detection instruction operation is performed, an instruction signal instructing switching to the noise detection mode is transmitted from the vehicle-side transmission antenna and received by the portable device-side reception antenna 10, and the reception unit 12 or the control unit 33 The operation mode is configured to be switched.

  In the first embodiment (including the modification), the reception unit 12 has a normal mode and a noise detection mode as its operation mode, and the noise voltage is only when the reception unit 12 is in the noise detection mode. Although the level is displayed, the voltage level of noise may be always displayed without setting such an operation mode. This also allows the user to check the noise reception status of the portable device. For example, the current consumption of the built-in battery can be reduced by changing the storage location of the portable device.

  In the first embodiment, the portable device side noise level display unit is provided as a display unit for displaying the voltage level of noise. However, the noise reception status of the portable device 1 can be confirmed only on the portable device side. There is no need to do. In addition to the portable device side, the vehicle side device may be able to confirm the noise reception status of the portable device 1. Specifically, the portable device 1 transmits from the portable device-side transmitting antenna information indicating the voltage level of noise determined by the receiving unit 12 and the portable device-side transmitting antenna for transmitting a signal to the vehicle-side device. The vehicle side device further includes a vehicle side reception antenna for wirelessly receiving a signal transmitted from the portable device side transmission antenna and information received by the vehicle side reception antenna. A display unit may be provided. Thereby, the user can confirm the noise reception status of the portable device 1 also on the vehicle-side information display unit. Therefore, when it is confirmed that the portable device receives a lot of noise when the user gets on, the portable device 1 is stored in a noisy environment from the next time, for example, the storage location of the portable device 1 is changed. You can prevent that. Therefore, the current consumption of the built-in battery can be reduced. In addition, as a vehicle side information display part, it is possible to employ | adopt LED and monitor screens, such as a vehicle-mounted navigation apparatus and a meter, for example.

It is a block diagram which shows the structure of 1st Embodiment about the portable device of the electronic key system which concerns on this invention. It is a figure which shows an example of the correspondence map of the voltage level of noise, and the lighting interval of LED. It is a figure which shows an example of the timing chart which concerns on the lighting-off mode of LED. It is a flowchart which shows the process sequence about the noise level display process performed by 1st Embodiment. It is a block diagram which shows the structure of 2nd Embodiment about the portable device of the electronic key system which concerns on this invention. It is a flowchart which shows the process sequence about the noise level display process performed by 2nd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1a ... Portable device, 10 ... Portable device side receiving antenna, 10a ... X-axis antenna, 10b ... Y-axis antenna, 10c ... Z-axis antenna, 11a-11c ... Variable capacitor, 12, 32 ... Receiver, 12a ... Transponder Function unit 13, 33 ... Control unit, 14 ... Oscillator, 15 ... Built-in battery, 16 ... Lock button (locking switch), 17 ... Unlock button (unlocking switch), 18 ... Luggage button, 19 ... LED (mobile) Machine side noise level display unit, light emitting element), 20 ... RF transmitter, 21 ... oscillator, 22 ... transmitting antenna

Claims (5)

An electronic key system that controls the vehicle according to a result of code verification using wireless communication between a portable device carried by a user and a vehicle-side device mounted on the vehicle,
The portable device is
A portable device-side receiving antenna for wirelessly receiving a signal transmitted from the vehicle-side device;
Determining whether or not the signal received by the mobile device side receiving antenna is noise, and determining the voltage level of the noise based on being determined to be noise;
A portable device-side noise level display for displaying the voltage level of the noise determined by the portable device-side receiver ;
Based on determining that a predetermined noise detection instruction operation has been performed, an operation mode switching unit that switches the operation mode of the portable device side reception unit from the normal mode to the noise detection mode;
A locking switch for locking the vehicle door; and an unlocking switch for unlocking the vehicle door;
The noise detection instruction operation is different from the locking operation using the locking switch and the unlocking operation using the unlocking switch, and is a predetermined operation using these locking switch and unlocking switch,
Only when the operation mode of the portable device side receiving unit is a noise detection mode, the portable device side receiving unit determines the voltage level of noise, and the portable device side noise level display unit displays the voltage level of noise. An electronic key system characterized by that. An electronic key system that controls the vehicle according to a result of code verification using wireless communication between a portable device carried by a user and a vehicle-side device mounted on the vehicle,
The portable device is
A portable device-side receiving antenna for wirelessly receiving a signal transmitted from the vehicle-side device;
Determining whether or not the signal received by the mobile device side receiving antenna is noise, and determining the voltage level of the noise based on being determined to be noise;
Based on determining that a predetermined noise detection instruction operation has been performed, an operation mode switching unit that switches the operation mode of the portable device side reception unit from the normal mode to the noise detection mode;
A portable device-side operation mode display for displaying the operation mode of the portable device;
A portable device-side noise level display unit that displays a voltage level of noise determined by the portable device-side receiver unit ;
Only when the operation mode of the portable device side receiving unit is a noise detection mode, the portable device side receiving unit determines the voltage level of noise, and the portable device side noise level display unit displays the voltage level of noise. An electronic key system characterized by that. The electronic key system according to claim 1 or 2 ,
The electronic key system characterized in that the operation mode switching unit switches the operation mode of the portable device side receiving unit from a noise detection mode to a normal mode based on a predetermined release condition being satisfied. The electronic key system according to claim 3 .
The portable device further includes a time measuring unit that measures an elapsed time since switching to the noise detection mode,
The electronic key system according to claim 1, wherein the release condition includes that a predetermined time has elapsed from a time measured by the time measuring unit. The electronic key system according to any one of claims 1 to 4 ,
The electronic key system characterized in that the portable device-side noise level display unit has a light emitting element, and the light emitting element is turned on and off in a pattern corresponding to the voltage level of the noise .

Images