JP2016094035A - Trigger device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a trigger device that can suppress an increase in the scale of a device.SOLUTION: The trigger device 10 transmits a trigger signal for controlling a tire sensor unit 113 for detecting a tire state. The trigger device 10 includes: a LF transmission circuit 13 for wirelessly transmitting the trigger signal; a non-contact feeder circuit 17 capable of receiving source power in a non-contact manner; and a common coil 14 used in common for wireless transmission of the trigger signal by the LF transmission circuit 13 and reception of the source power by the non-contact feeder circuit 17.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a trigger device that transmits a trigger signal for controlling a tire state detection device that detects a state of a tire.

  Conventionally, as a trigger device, a trigger signal for requesting transmission of information related to a tire state is wirelessly transmitted to a tire state detection device that detects a tire state (for example, air pressure), and the state of the tire is specified. What is possible is known.

  As such a trigger device, for example, as shown in Patent Document 1, in addition to a function for unlocking and locking a vehicle, a trigger signal according to a user's operation is provided on a remote controller portable by the user. Is disclosed that is equipped with a function for wirelessly transmitting a message. Thus, before the user drives the vehicle, the vehicle can be unlocked and a start-up inspection such as checking the state of the tire can be performed.

JP 2005-186659 A

  By the way, in such a trigger device, for example, it can be carried by the user, but it must be replaced when a battery for supplying power is exhausted. Therefore, it is considered that the trigger device is provided with a function of supplying a power supply voltage. However, since a member for supplying power is mounted and the device is increased in size, the increase in the size of the device can be suppressed. It is desired.

  This invention was made paying attention to the problem which exists in such a prior art, and the objective is to provide the trigger apparatus which can suppress the enlargement of an apparatus.

  A trigger device that solves the above problems is a trigger device that transmits a trigger signal for controlling a tire state detection device that detects a state of a tire, and a wireless transmission circuit that wirelessly transmits the trigger signal, in a non-contact manner. It is provided with a non-contact power supply circuit capable of receiving power supply power, and a shared coil shared in wireless transmission of the trigger signal by the wireless transmission circuit and power supply power reception by the non-contact power supply circuit. To do.

  According to this, the number of coils can be reduced and the cost can be reduced as compared with a case where a coil for wireless transmission of a trigger signal by a wireless transmission circuit and a coil for power supply reception by a non-contact power supply circuit are provided. While suppressing, the enlargement of an apparatus can be suppressed.

  The trigger device may include a changeover switch that can switch between the wireless transmission of the trigger signal by the wireless transmission circuit and the reception of power supply power by the non-contact power supply circuit. .

According to this, a shared coil can be selectively used by providing a changeover switch.
The trigger device includes a capacitor connectable to the shared coil, and when the shared coil is used for wireless transmission of the trigger signal by the wireless transmission circuit, the shared coil and the capacitor are connected in series. While forming the series resonant circuit to be connected, when the shared coil is used for receiving power from the contactless power supply circuit, a parallel resonant circuit for connecting the shared coil and the capacitor in parallel may be formed. Good.

  According to this, the resonance circuit corresponding to the wireless transmission circuit and the non-contact power feeding circuit can be connected by the changeover switch so as to be switchable, and the series resonance circuit and the parallel resonance circuit can be selectively used.

The trigger device may be configured to be connectable to a mobile terminal, and the non-contact power supply circuit may be configured to be able to supply received power to the mobile terminal.
According to this, the non-contact power feeding circuit can supply the received power supply power to the portable terminal, can improve the function of the trigger device, and is simple.

  According to the present invention, an increase in the size of the apparatus can be suppressed.

The schematic block diagram which shows the tire condition detection system containing the trigger apparatus of embodiment. (A) is a figure which shows the circuit structure of the tire sensor unit of embodiment, (b) is a figure which shows the circuit structure of the trigger apparatus of embodiment. (A) is a figure which shows the circuit structure of the trigger apparatus of embodiment, (b) is a figure which shows the circuit structure of the portable terminal of embodiment.

Hereinafter, an embodiment embodying a tire condition detection system including a trigger device will be described with reference to FIGS. 1 and 2.
As shown in FIG. 1, a tire state detection system S is mounted on the vehicle 110. The four wheels 101 to 104 of the vehicle 110 include a wheel part 105 and a tire 106 attached to the wheel part 105.

  The tire condition detection system S includes a tire condition detection device 130 for detecting the condition of the tire 106 and a trigger device 10 that outputs a trigger signal for controlling the tire condition detection device 130.

  The tire condition detection device 130 includes a tire sensor unit 113 that is attached to each of the four wheels 101 to 104 of the vehicle 110, and a receiver unit 131 that is installed on the vehicle body of the vehicle 110.

  A tire sensor unit 113 is disposed on the wheel portion 105 integrally with the tire valve. The tire sensor unit 113 detects the state of the tire 106 such as the air pressure (tire pressure) and temperature (in-tire temperature) in the tire 106, and transmits a transmission signal (detection result information) regarding the detection result to the receiver unit 131 or Wirelessly transmit to the trigger device 10.

  In the present embodiment, the trigger device 10 sends to the tire sensor unit 113 a trigger signal (hereinafter referred to as “state request trigger signal”) that requests transmission of a signal related to the state of the tire 106 in accordance with the operation of the operation unit 11. Wireless transmission. And the trigger apparatus 10 can receive the transmission signal (henceforth "state detection result signal") regarding a detection result from the tire sensor unit 113, and the information based on the received state detection result signal is a display part. 12 is displayed.

  2B, the trigger device 10 includes an operation unit 11, a display unit 12, an LF transmission circuit 13, a shared coil 14, an RF communication circuit 15, an RF communication antenna 16, a non-contact power feeding circuit 17, a storage battery. 18 and a trigger controller 19. The trigger device 10 operates by supplying power from the storage battery 18.

  The operation unit 11 outputs an operation detection signal to the trigger controller 19 when an operation by the user is detected. The display unit 12 displays the detection result of the state of the tire 106 according to the control signal from the trigger controller 19.

  The non-contact power supply circuit 17 is a circuit for storing the power supply supplied through the shared coil 14 in the storage battery 18. In particular, in the present embodiment, an electromagnetic induction method is used, and the shared coil 14 is in non-contact with an external coil provided outside, and couples a magnetic flux caused by a current flowing through the external coil. The contact power supply circuit 17 can receive power. In this way, the storage battery 18 stores the power supply received by the non-contact power supply circuit 17.

  The LF transmission circuit 13 as a wireless transmission circuit is a circuit that transmits a signal through a shared coil 14 as an antenna for LF transmission using radio waves in a predetermined frequency band (135 kHz in the present embodiment). A circuit for transmitting a request trigger signal.

  The RF communication circuit 15 is a circuit that transmits and receives signals through the RF communication antenna 16 using radio waves in a predetermined frequency band (in this embodiment, 2.4 GHz), and in particular, a circuit that receives a state detection result signal. It is.

  In the present embodiment, the shared coil 14 is an air-core coil, and is shared by the wireless transmission of the state request trigger signal by the LF transmission circuit 13 and the reception of the power supply by the non-contact power supply circuit 17. A changeover switch SW is connected to the shared coil 14 so that it can be switched between wireless transmission of a state request trigger signal by the LF transmission circuit 13 and reception of power supply power by the non-contact power supply circuit 17. .

  When the shared coil 14 is connected to the LF transmission circuit 13 by the changeover switch SW, a series resonance circuit 21 in which the shared coil 14 and the capacitor C1 are connected in series is formed. The LF transmission circuit 13 includes the series resonance circuit 21. Will be connected. When the shared coil 14 is connected to the non-contact power supply circuit 17 by the changeover switch SW, a parallel resonance circuit 22 in which the shared coil 14 and the capacitor C2 are connected in parallel is formed. The non-contact power supply circuit 17 includes a parallel resonance circuit. 22 will be connected.

  As shown in FIG. 2A, the trigger controller 19 includes a microcomputer including a CPU 19a and a storage unit 19b (RAM, ROM, etc.). The storage unit 19b of the trigger controller 19 stores a program that comprehensively controls the operation of the trigger device 10. Further, the storage unit 19 b of the trigger controller 19 stores identification information that can identify the tire sensor unit 113 disposed in each tire 106. The state detection result signal includes such identification information, and the trigger controller 19 receives the state detection result signal, and thereby determines the tire sensor unit 113 that is the transmission source of the state detection result signal. Can be identified.

  The trigger controller 19 causes the LF transmission circuit 13 to transmit a state request trigger signal when the operation of the operation unit 11 is detected. When the trigger controller 19 receives the state detection result signal from the RF communication circuit 15, the trigger controller 19 displays information on the state of the tire 106 on the display unit 12 based on the signal.

  The trigger controller 19 controls the changeover switch SW so that it can be switched. Specifically, in a normal time, the trigger controller 19 controls the changeover switch SW so that the shared coil 14 is connected to the non-contact power feeding circuit 17. As a result, the parallel resonance circuit 22 is connected to the non-contact power supply circuit 17, and the shared coil 14 is used to receive power supply power in the non-contact power supply circuit 17. When the operation of the operation unit 11 is detected, the trigger controller 19 controls the changeover switch SW so that the shared coil 14 is connected to the LF transmission circuit 13 before the state request trigger signal is wirelessly transmitted. As a result, the series resonance circuit 21 is connected to the LF transmission circuit 13, and the shared coil 14 is used for wireless transmission of the state request trigger signal in the LF transmission circuit 13. Then, after causing the LF transmission circuit 13 to transmit the state request trigger signal, the trigger controller 19 controls the changeover switch SW so that the shared coil 14 is connected to the non-contact power feeding circuit 17.

  Each tire sensor unit 113 includes a sensor unit controller 114, a pressure sensor 115, a temperature sensor 116, an LF reception circuit 117, an LF reception antenna 118, an RF communication circuit 119, an RF communication antenna 120, and a battery 121. The tire sensor unit 113 operates by supplying power from the battery 121.

The pressure sensor 115 detects the corresponding tire pressure. The temperature sensor 116 detects a corresponding tire temperature.
The LF reception circuit 117 is a circuit that receives a signal through the LF reception antenna 118 using radio waves in a predetermined frequency band (135 kHz in the present embodiment). In particular, the LF reception circuit 117 receives a state request trigger signal from the trigger device 10. It is a circuit to receive.

  The RF communication circuit 119 is a circuit that transmits and receives signals through the RF communication antenna 120 using radio waves in a predetermined frequency band (in the present embodiment, 2.4 GHz). In particular, the state detection result signal is transmitted to the receiver unit. 131 is a circuit for transmitting to 131 and the trigger device 10.

  The sensor unit controller 114 includes a microcomputer including a CPU 114a and a storage unit 114b (RAM, ROM, etc.). The storage unit 114b of the sensor unit controller 114 stores a program that comprehensively controls the operation of the tire sensor unit 113.

  The sensor unit controller 114 receives detection signals from the pressure sensor 115 at predetermined intervals, and stores pressure data based on these detection signals in the storage unit 114b. Further, the sensor unit controller 114 receives detection signals from the temperature sensor 116 at predetermined intervals, and stores temperature data based on the detection signals in the storage unit 114b.

  A threshold for comparison with the pressure data detected by the pressure sensor 115 is stored in the storage unit 114b of the sensor unit controller 114 in advance. The threshold value is information unique to the tire 106, and is set to a low level with a margin more than the pressure data detected when the tire air pressure enclosed by the wheel portion 105 and the tire 106 becomes excessively low. . When the pressure data detected by the pressure sensor 115 exceeds the threshold value, the sensor unit controller 114 generates a state detection result signal indicating an abnormality in the air pressure and causes the RF communication circuit 119 to transmit it.

  In addition, a threshold for comparison with temperature data detected by the temperature sensor 116 is stored in the storage unit 114b of the sensor unit controller 114 in advance. The threshold value is information unique to the tire 106, and is set to a higher level with a margin than the temperature data detected when the temperature inside the tire enclosed by the wheel portion 105 and the tire 106 becomes excessively high. Yes. When the temperature data detected by the temperature sensor 116 exceeds the threshold value, the sensor unit controller 114 generates a state detection result signal indicating a temperature abnormality and causes the RF communication circuit 119 to transmit it.

  On the other hand, when the pressure data detected by the pressure sensor 115 does not exceed the threshold value and when the temperature data detected by the temperature sensor 116 does not exceed the threshold value, the sensor unit controller 114 indicates an abnormality. The detection result signal is not generated.

  In the present embodiment, the sensor unit controller 114 is configured to perform predetermined times (for example, four times) even when the pressure data detected by the pressure sensor 115 or the temperature data detected by the temperature sensor 116 does not exceed the threshold value. ) Causes the RF communication circuit 119 to transmit a state detection result signal indicating normality every time.

  In the present embodiment, when the sensor unit controller 114 receives the state request trigger signal from the trigger device 10 by the LF receiving circuit 117, the sensor unit controller 114 causes the RF communication circuit 119 to transmit a state detection result signal.

  As shown in FIG. 1, the receiver unit 131 includes a receiver unit controller 133 and an RF communication circuit 135. A display 138 is connected to the receiver unit controller 133 of the receiver unit 131. The RF communication circuit 135 sends a state detection result signal received from each tire sensor unit 113 through the RF communication antenna 132 to the receiver unit controller 133.

  The receiver unit controller 133, based on the state detection result signal from the RF communication circuit 135, when the data relating to the state of the tire 106 (tire pressure and temperature in the tire) corresponding to the tire sensor unit 113 of the transmission source exceeds a threshold value In addition, information related to the state of the tire 106 is displayed on the display 138. The indicator 138 is arranged in the visible range of the passenger of the vehicle 110 such as the passenger compartment, and displays (notifies) an abnormality in the state of the tire 106 specified by the receiver unit controller 133.

Next, the operation of the tire condition detection system S including the trigger device 10 of the present embodiment will be described.
In the present embodiment, the trigger device 10 is supplied with power from the built-in storage battery 18. Normally, the changeover switch SW is controlled so that the shared coil 14 is used to receive power supply power in the non-contact power feeding circuit 17. As a result, the power supply power can be supplied to the non-contact power supply circuit 17 via the shared coil 14 (parallel resonance circuit 22).

  When the operation unit 11 is operated, the changeover switch SW is controlled to use the shared coil 14 for wireless transmission of the state request trigger signal in the LF transmission circuit 13. Thereby, the LF transmission circuit 13 is configured to be able to wirelessly transmit the state request trigger signal via the shared coil 14 (series resonance circuit 21).

As described above in detail, the present embodiment has the following effects.
(1) The trigger device 10 includes a shared coil 14 that is shared between the wireless transmission of the state request trigger signal by the LF transmission circuit 13 and the reception of the power supply by the non-contact power supply circuit 17. Thereby, for example, the number of coils can be reduced and the cost can be reduced as compared with a case where a coil for wireless transmission of a trigger signal by a wireless transmission circuit and a coil for receiving power supply power by a non-contact power supply circuit are provided. While suppressing, the enlargement of an apparatus can be suppressed.

  (2) The trigger device 10 includes a change-over switch SW that can switch between the wireless transmission of the state request trigger signal and the reception of the power supply by the non-contact power supply circuit 17 for the shared coil. Thereby, the shared coil 14 can be selectively used.

  (3) When the shared coil 14 is used for wireless transmission of the state request trigger signal by the LF transmission circuit 13, the series resonance circuit 21 that connects the shared coil 14 and the capacitor C1 in series is connected to the LF transmission circuit 13. On the other hand, when the shared coil 14 is used for receiving the power supply by the contactless power supply circuit 17, the parallel resonance circuit 22 that connects the shared coil 14 and the capacitor C <b> 2 in parallel is connected to the contactless power supply circuit 17. For this reason, the resonance circuit corresponding to the LF transmission circuit 13 and the non-contact power supply circuit 17 can be switched by the changeover switch SW, and the series resonance circuit 21 and the parallel resonance circuit 22 can be selectively used. it can.

[Second Embodiment]
In the second embodiment, the trigger device 10 is configured to be connectable to a mobile terminal instead of a single unit.

  As a specific example, as illustrated in FIG. 3A, the trigger device 10 includes an operation unit and a display unit, but includes an external connection unit 20 that can be connected to the mobile terminal 200. The external connection unit 20 corresponds to, for example, a universal serial bus that can communicate and supply power.

  In the trigger device 10, when the trigger controller 19 receives a transmission request signal from the mobile terminal 200, the trigger controller 19 causes the LF transmission circuit 13 to transmit a state request trigger signal. When the trigger controller 19 receives the state detection result signal from the RF communication circuit 15, the trigger controller 19 transmits a signal based on the state detection result signal to the portable terminal 200 via the external connection unit 20.

  As illustrated in FIG. 3B, the mobile terminal 200 includes an operation unit 201, a display unit 202, a storage battery 203, an external connection unit 204, and a controller 205. The portable terminal 200 operates by supplying power from the storage battery 203. The mobile terminal 200 corresponds to a mobile phone or a tablet terminal.

  When the operation by the user is detected, the operation unit 201 transmits an operation detection signal to the controller 205. The display unit 202 displays a predetermined image in response to a control signal from the controller 205. The external connection unit 204 can be connected to the external connection unit 20 of the trigger device 10 and can communicate and supply power.

  The controller 205 includes a microcomputer including a CPU 205a and a storage unit 205b (RAM, ROM, etc.). The storage unit 205b of the controller 205 stores a program that comprehensively controls the operation of the mobile terminal 200.

  When the controller 205 receives a predetermined operation detection signal from the operation unit 201, the controller 205 transmits a transmission request signal to the trigger device 10 via the external connection unit 204. When the controller 205 receives the state detection result signal via the external connection unit 204, the controller 205 causes the display unit 202 to display an image based on the state detection result signal.

  In the present embodiment, the power supplied by the contactless power supply circuit 17 of the trigger device 10 can be supplied to the mobile terminal 200 via the external connection unit 20. Then, in the mobile terminal 200, the power supply received via the external connection unit 204 is stored in the storage battery 203.

As described above in detail, the second embodiment has the following effects in addition to the effects (1) to (3) in the first embodiment.
(4) The non-contact power supply circuit 17 can supply the received power supply power to the portable terminal 200 via the external connection unit 20, can improve the function of the trigger device 10, and is simple.

  (5) The trigger device 10 is configured to be able to communicate with the portable terminal 200 including the operation unit 201 via the external connection unit 20. For this reason, the trigger device 10 can receive information according to the operation of the operation unit 201 from the portable terminal 200, and the trigger device 10 can be configured not to include the operation unit itself, thereby reducing costs. The enlargement of the apparatus can be suppressed.

  (6) The trigger device 10 is configured to be able to communicate with the mobile terminal 200 including the display unit 202 via the external connection unit 20. For this reason, the trigger device 10 can transmit information for displaying an image related to control to the mobile terminal 200, and the trigger device 10 can be configured not to include the display unit itself, thereby reducing costs. The enlargement of the apparatus can be suppressed.

In addition, you may change embodiment as follows.
In the second embodiment, the trigger device 10 is configured not to include the operation unit or the display unit. However, the present invention is not limited thereto, and for example, the trigger device 10 may include the operation unit or the display unit. It is preferable that the trigger device 10 includes an operation unit and a display unit that are more simplified than the operation unit and the display unit of the portable terminal 200.

-In 2nd Embodiment, as an external connection part, connection systems other than a universal serial bus may be used, and it is preferable that communication and supply of a power supply voltage are possible.
In the above-described embodiment, the electrically switchable switch SW that can be controlled by the trigger controller 19 is used. However, the present invention is not limited to this, and the switch SW that cannot be controlled by the trigger controller 19 is physically switchable. A changeover switch may be employed, or a combination thereof. In this case, it is preferable that the operation unit 11 or the like can be switched by a user operation.

  In the above embodiment, the air-core coil is used as the shared coil, but is not limited thereto, for example, a thin plate-shaped coil using a spiral pattern may be used, for example, due to the characteristics of the metal part, A magnetic sheet may be attached to the shared coil.

  In the above embodiment, the capacitor C1 used for the series resonant circuit 21 and the capacitor C2 used for the parallel resonant circuit 22 may have the same capacity or different capacities. In this case, for example, when the transmission frequency of the trigger signal in the LF transmission circuit 13 and the reception frequency of the power supply power in the non-contact power supply circuit 17 are different, the capacitances of the capacitors are made different so that the circuits 13, 17 Capacitors with capacities suitable for can be connected.

  -Although the storage battery using lithium was employ | adopted as the storage battery 18, not only this but another storage battery, such as a storage battery using lead storage battery or nickel, may be employ | adopted, and the primary battery and battery itself which are not storage batteries are used. The structure which is not provided may be sufficient.

  The trigger device 10 transmits a state request trigger signal that requests a detection result of the state of the tire 106, but is not limited thereto, and may transmit a setting change trigger signal related to a setting change of the tire sensor unit 113, for example. A combination of these may also be used. That is, the trigger device 10 may be any device that transmits a trigger signal for controlling the tire state detection device that detects the state of the tire.

For example, although the tire sensor unit 113 is adopted as an object with which the trigger device 10 communicates wirelessly, the present invention is not limited thereto, and for example, a receiver unit 131 may be adopted.
For example, as a tire state detection device that detects a state of a tire, a configuration in which the receiver unit 131 is not provided may be used as long as at least a device such as the tire sensor unit 113 is provided.

  For example, the trigger device 10 may include an LF communication circuit that can transmit a trigger signal and can receive a state detection result signal. In this case, the trigger device 10 may be configured not to include the RF communication circuit 15. For example, the shared coil 14 may be used for signal transmission / reception.

  For example, although the LF transmission circuit 13 is adopted as the wireless transmission circuit, the present invention is not limited to this. For example, as long as the communication is performed through the shared coil 14 using radio waves of another frequency band such as short-range wireless communication. Good.

  ・ While the tire pressure or the temperature inside the tire is determined to be abnormal by comparing with a threshold value, it is not limited to this. For example, it is abnormal by monitoring the amount of change in the tire pressure or the temperature inside the tire. It may be determined whether or not, or a combination thereof.

  Any one of the tire air pressure and the tire internal temperature may be detected as the state of the tire 106, and other than the tire air pressure and the tire internal temperature may be detected. For example, the wear signal of the tire 106, abnormal vibration, abnormality of the sensor unit controller 114 itself, abnormality of the pressure sensor 115 itself, abnormality of the temperature sensor 116 itself, voltage drop of the battery 121, and the like may be detected, and a transmission signal may be transmitted. A combination of these may also be used.

  The trigger device 10 may determine whether the state of the tire 106 is normal or abnormal, and the tire sensor unit 113 determines whether the state of the tire 106 is normal or abnormal. It does not have to be. That is, the tire sensor unit 113 may detect the state of the tire 106 and output a signal related to the detection result.

-For example, the tire state detection system including the trigger device 10 as described above has the same effect and may have such a configuration.
Next, a technical idea that can be grasped from the above embodiment and another example will be added below.

(A) A storage battery for storing the power supply received by the non-contact power supply circuit is provided.
(B) The shared coil is non-contact with an external coil provided outside, couples a magnetic flux generated when a current is passed through the external coil, and allows the non-contact power supply circuit to receive power. Features.

  DESCRIPTION OF SYMBOLS S ... Tire condition detection system, 10 ... Trigger device, 11, 201 ... Operation part, 12, 202 ... Display part, 13 ... LF transmission circuit, 14 ... Shared coil, 15, 119 ... RF communication circuit, 16, 120 ... RF Communication antenna, 17 ... Non-contact power supply circuit, 18, 203 ... Storage battery, 19 ... Trigger controller, 20, 204 ... External connection part, 101-104 ... Wheel, 105 ... Wheel part, 106 ... Tire, 110 ... Vehicle, 113 DESCRIPTION OF SYMBOLS ... Tire sensor unit, 114 ... Sensor unit controller, 115 ... Pressure sensor, 116 ... Temperature sensor, 117 ... LF receiving circuit, 121 ... Battery, 130 ... Tire state detection apparatus, 133 ... Receiver unit controller, 200 ... Portable terminal.

Claims (4)

In a trigger device that transmits a trigger signal for controlling a tire state detection device that detects a state of a tire,
A wireless transmission circuit for wirelessly transmitting the trigger signal;
A contactless power supply circuit capable of receiving power supply power in a contactless manner;
A trigger device comprising: a shared coil shared by wireless transmission of the trigger signal by the wireless transmission circuit and power supply power reception by the non-contact power supply circuit.   2. The trigger device according to claim 1, further comprising: a selector switch capable of switching whether to use the shared coil for wireless transmission of the trigger signal by the wireless transmission circuit or power supply power reception by the non-contact power supply circuit. A capacitor that can be connected to the shared coil;
When the shared coil is used for wireless transmission of the trigger signal by the wireless transmission circuit, the changeover switch forms a series resonance circuit that connects the shared coil and the capacitor in series, while the contactless power supply circuit 3. The trigger device according to claim 2, wherein when the shared coil is used for receiving power from the power source, a parallel resonance circuit is formed that connects the shared coil and the capacitor in parallel. It can be connected to a mobile device,
The trigger device according to any one of claims 1 to 3, wherein the non-contact power supply circuit is capable of supplying received power to the mobile terminal.