JP2013130013A - Electronic key system for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic key system for a vehicle capable of suppressing its malfunction even under an environment in which spike noises occur.SOLUTION: In the electronic key system for the vehicle, radio communication is performed between an on-vehicle machine 2 and a portable machine 1 on condition that the portable machine 1 is located in a communication area covered by the on-vehicle machine 2. When receiving a wake signal transmitted from the on-vehicle machine 2, the portable machine 1 measures a RSSI value for the wake signal and transmits a response signal including the measurement result to the on-vehicle machine 2. The on-vehicle machine 2 determines the position of the portable machine 1 in the communication area on the basis of the RSSI value included in the response signal and executes vehicle control depending on the determination result. Herein, the portable machine 1 measures the RSSI for the wake signal three times. The on-vehicle machine 2 determines the position of the portable machine 1 on the basis of an average value for the remaining two RSSI values excluding the strongest one, out of the three measurement results of the RSSI values measured by the portable machine 1.

Description

  The present invention relates to an electronic key system that executes various controls of a vehicle through wireless communication between the vehicle and an electronic key.

  When the user holding the portable device (electronic key) touches the door knob of the vehicle, the vehicle door is unlocked, and the engine is started when the user presses an engine switch provided on the dashboard. So-called electronic key systems are well known. Conventionally, as such an electronic key system, for example, a system described in Patent Document 1 is known.

  In the electronic key system described in Patent Document 1, a plurality of transmitters are provided for respectively transmitting radio signals to a plurality of communication areas set outside and inside the vehicle compartment. If the user touches the door knob of the vehicle, the first radio signal is transmitted from each transmitter. And when these 1st radio signals are received by the portable machine which a user possesses, a portable machine measures the value of received signal strength (RSSI) about the 1st radio signal transmitted from each transmitter, respectively. In addition, a measurement result of each RSSI value and a second radio signal including its own identification code are transmitted. Then, the second radio signal transmitted from the portable device is received by the in-vehicle device via the receiver mounted on the vehicle. When the in-vehicle device receives the second wireless signal in this manner, the mobile device authentication is performed by collating the identification code of the portable device included in the second wireless signal with the identification code included in the built-in memory. I do. Further, the position of the portable device is determined based on each RSSI value included in the second wireless signal. When the authentication of the portable device is established and it is determined that the portable device is located around the vehicle door, the vehicle door is unlocked.

  According to such a configuration, since the position of the portable device can be determined with high accuracy, vehicle control according to the position of the portable device, in other words, according to the position of the user is more appropriately executed. become. Therefore, it is possible to improve the reliability as an electronic key system.

JP 2006-348497 A

  By the way, in such an electronic key system for a vehicle, if noise may be mixed in the first wireless signal transmitted from the transmitter of the vehicle, the portable device will be determined by the RSSI value of the first wireless signal. There is a risk of measuring the RSSI value of noise. The noise mixed in the first radio signal includes, for example, a so-called spike noise that has a very short generation time and a strong intensity generated by a spark plug or a wiper drive motor mounted on the vehicle. is there. And if the portable device sometimes measures the RSSI value of such spike noise, the RSSI value of spike noise is included in the second radio signal transmitted from the portable device. The position of the portable device is determined based on the RSSI value of spike noise. In this case, it becomes difficult to appropriately determine the position of the portable device, which makes it difficult to execute appropriate vehicle control according to the position of the portable device, which hinders the operation of the electronic key system of the vehicle. It might be.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a vehicle electronic key system capable of suppressing malfunction even under an environment where spike noise occurs. is there.

  In order to solve the above problem, the invention according to claim 1 is provided between the in-vehicle device and the portable device on the condition that the portable device is located in a communication area of the in-vehicle device mounted on the vehicle. Wireless communication is performed, and when the portable device receives the first wireless signal transmitted from the in-vehicle device, the portable device measures the received signal strength and sends the second wireless signal including the measurement result to the in-vehicle device. The vehicle-mounted device determines the position of the portable device in the communication area based on the measurement result of the received signal strength included in the second radio signal, and performs vehicle control according to the determination result. In the electronic key system of the vehicle to be executed, the portable device performs measurement of the received signal strength of the first wireless signal a plurality of times, and the in-vehicle device measures a plurality of received signal strengths measured by the portable device. Of the results, the strength is high And summarized in that to determine the position of the portable device on the basis of the remaining measurements excluding a certain number of measurements from the.

  Spike noise is generally single-shot noise, and only a part of the entire radio signal is affected by the spike noise. Therefore, as in the above configuration, if the received signal strength of the first radio signal transmitted from the in-vehicle device is measured a plurality of times in the portable device, even if spike noise is mixed in the first radio signal. All of the plurality of measurement results are rarely affected by spike noise, and usually one of the measurement results is affected by spike noise. And in the in-vehicle device, since the position of the portable device is determined based on the remaining measurement results excluding a certain number of measurement results from the large one of the multiple measurement results, the measurement result is less affected by spike noise. Based on this, the position of the portable device is determined. As a result, the position of the portable device can be determined with higher accuracy, and malfunction of the electronic key system can be suppressed.

  According to a second aspect of the present invention, in the electronic key system for a vehicle according to the first aspect, the determination of the position of the portable device is performed by calculating a certain number of measurement results from the one having a higher strength among the plurality of measurement results. The gist is that it is performed based on the average value of the remaining measurement results.

  If the average value of the measurement results of the received signal strength is obtained and the position of the portable device is determined based on the average value as in the same configuration, the influence due to variations in the measurement results of the received signal strength is suppressed. Meanwhile, the position of the portable device can be determined. Thereby, since the position of the portable device can be determined with higher accuracy, it is possible to more accurately suppress malfunction of the electronic key system.

A third aspect of the present invention is the electronic key system for a vehicle according to the first or second aspect, wherein the predetermined number is set to one.
Since spike noise is a single noise, one of a plurality of measurement results of received signal strength measured by a portable device is often affected by the noise. Therefore, as described above, the position of the portable device is determined based on the remaining measurement results excluding only the highest strength among the plurality of measurement results of the received signal strength measured by the portable device. For example, the position of the portable device can be determined while suppressing the influence of spike noise. And, in this way, if it is a method of excluding only one of a plurality of measurement results measured by the portable device, it is possible to set the number of times of measurement of the received signal strength to about several times. The time taken to measure the intensity does not increase significantly. As a result, the communication time between the portable device and the in-vehicle device can be shortened as much as possible.

  According to the vehicle electronic key system of the present invention, malfunction can be suppressed even in an environment where spike noise occurs.

The block diagram which shows the system configuration | structure about one Embodiment of the electronic key system of the vehicle concerning this embodiment. The top view which shows the planar structure of a vehicle. (A)-(c) is a time chart which shows the content of the signal each transmitted from the 1st and 2nd transmitter of an onboard equipment, and a portable device. The figure which shows typically the flame | frame structure of the wake signal transmitted from the 1st and 2nd transmitter of a vehicle equipment in the electronic key system of the vehicle of the embodiment. The flowchart which shows the procedure of the process which measures the RSSI value of the wake signal by the electronic key system of the vehicle of the embodiment. The figure which shows typically a mode that the RSSI value of a wake signal is calculated in the electronic key system of the vehicle of the embodiment.

Hereinafter, an embodiment of an electronic key system for a vehicle according to the present invention will be described with reference to FIGS.
As shown in FIG. 1, in the electronic key system for a vehicle according to the present embodiment, various communication controls are performed by wireless communication between a portable device 1 carried by the user and an in-vehicle device 2 mounted on the vehicle. The

  Among these, the portable device 1 includes a receiver 10 that receives a radio signal transmitted from the in-vehicle device 2, and a transmitter 11 that transmits a radio signal to the in-vehicle device 2. When receiving the radio signal transmitted from the in-vehicle device 2, the receiver 10 performs reception processing and outputs the received signal to the portable device control unit 13 that executes various controls of the portable device 1. In addition, the receiver 10 is provided with an RSSI circuit 12 that detects a value of received signal strength (RSSI) of a received radio signal. When the RSSI circuit 12 detects the RSSI value of the radio signal, the RSSI circuit 12 outputs the detection result to the portable device control unit 13. The portable device control unit 13 transmits a wireless signal from the transmitter 11 based on a wireless signal received via the receiver 10. When the wireless signal received via the receiver 10 is a wake signal, the portable device control unit 13 activates the portable device 1 and sends an ACK signal indicating that the portable device 1 has been activated via the transmitter 11. It transmits to the vehicle equipment 2. In addition, when receiving the wake signal, the portable device control unit 13 detects the RSSI value through the RSSI circuit 12 and stores the detection result in the built-in memory 13a. Thus, in the present embodiment, the first radio signal used for measuring the RSSI value is a wake signal. On the other hand, when the wireless signal received via the receiver 10 is a request signal, the portable device control unit 13 determines the RSSI value of the wake signal stored in the memory 13a and the identification code (ID code) that is authentication information. Is generated from the transmitter 11. Thus, in the present embodiment, the second radio signal including the measurement result of the RSSI value is a response signal.

The in-vehicle device 2 includes first and second transmitters 20 and 21 that transmit wireless signals to a predetermined communication area, and a receiver 22 that receives wireless signals transmitted from the portable device 1.
As shown in FIG. 2, the first transmitter 20 is provided on the door of the driver's seat, and sends a radio signal to the first communication area A1 set around the outside of the driver's door and in the passenger compartment. Send. The second transmitter 21 is provided at the door of the passenger seat and transmits a radio signal to the second communication area A2 set around the outside of the passenger seat door and in the passenger compartment. The first and second communication areas A1 and A2 are set so that the respective areas set in the passenger compartment overlap each other. Further, when receiving the radio signal transmitted from the portable device 1, the receiver 22 shown in FIG. 1 performs reception processing and outputs the received signal to the in-vehicle control unit 29 that executes various controls of the vehicle.

  The in-vehicle device 2 includes an engine switch 23 that is operated when the engine is started and a lock switch 24 that is operated when the vehicle door is locked. The engine switch 23 is a type of switch pressed by the user, and is provided on the dashboard of the vehicle as shown in FIG. When the user presses the engine switch 23, the engine switch 23 outputs an operation signal indicating that to the vehicle-mounted control unit 29. The lock switch 24 is also a type of switch that is pressed by the user, and is provided on the door knob of the vehicle as shown in FIG. When the lock switch 24 is pressed down by the user, the lock switch 24 outputs an operation signal indicating that to the in-vehicle control unit 29.

  Furthermore, as shown in FIG. 1, the in-vehicle device 2 is a sensor for detecting a user's vehicle operation, and a brake sensor 25 that detects the amount of depression of the brake pedal of the vehicle, and whether or not the user's hand has touched the door knob. A touch sensor 26 for detecting the above is provided. The brake sensor 25 detects whether or not the user has operated the brake pedal, and outputs a signal according to the detected presence or absence of the operation to the in-vehicle control unit 29. Further, the touch sensor 26 is composed of, for example, a capacitance sensor, and detects whether or not the user's hand has touched the door knob, and outputs the detection result to the in-vehicle control unit 29.

  The in-vehicle control unit 29 transmits radio signals from the first and second transmitters 20 and 21 based on the outputs of the switches 23 and 24 and the sensors 25 and 26 or receives the signals via the receiver 22. Various vehicle controls are executed based on the radio signal.

When any one of the following conditions (a1) to (a3) is satisfied, the in-vehicle control unit 29 generates a wake signal and outputs the wake signal to the first transmitter 20 as shown in FIG. Send from.
(A1) Detecting that the switch 23 is pressed based on the output of the engine switch 23.

(A2) Detecting that the switch 24 has been pressed based on the output of the lock switch 24.
(A3) Detecting that the user's hand touches the doorknob based on the output of the touch sensor 26.

  Here, when the portable device 1 is located in the first communication area A1 illustrated in FIG. 2, the ACK is received based on the reception of the wake signal from the portable device 1, as shown in FIG. Since the signal is transmitted, the in-vehicle control unit 29 receives the ACK signal transmitted from the portable device 1 via the receiver 22. When receiving the ACK signal in this manner, the in-vehicle control unit 29 generates a request signal and transmits it from the first transmitter 20 as shown in FIG. And as shown in FIG.3 (c) based on transmission of this request signal, if a response signal is transmitted from the portable device 1, the vehicle-mounted control part 29 will receive a response signal via the receiver 22. FIG. . At this time, the in-vehicle controller 29 authenticates the portable device 1 by collating the identification code included in the response signal with the identification code stored in the built-in memory 29a. If the identification codes match, it is determined that authentication of the portable device 1 has been established.

  On the other hand, the response signal received by the in-vehicle control unit 29 includes the RSSI value of the wake signal, and there is a correlation between this RSSI value and the distance from the first transmitter 20 to the portable device 1. There is. Specifically, there is a correlation that the distance from the first transmitter 20 to the portable device 1 is shorter as the RSSI value is larger. In the present embodiment, the relationship between the RSSI value of such a wake signal and the distance from the first transmitter 20 to the portable device 1 is obtained through an experiment or the like, and these relationships are controlled in the vehicle as a map. It is stored in the memory 29a of the unit 29. The in-vehicle control unit 29 calculates the distance from the first transmitter 20 to the portable device 1 from the RSSI value of the wake signal included in the response signal, using the map stored in the memory 29a.

  The in-vehicle controller 29 transmits a wake signal from the second transmitter 21 as shown in FIG. 3B following the transmission of the wake signal and the request signal from the first transmitter 20. At this time, if the portable device 1 is located in the second communication area A2 illustrated in FIG. 2, the second transmitter 21 starts as shown in FIGS. 3 (b) and 3 (c). The request signal and the ACK signal and response signal from the portable device 1 are transmitted in the same manner. And the vehicle-mounted control part 29 carries out map calculation of the distance from the 2nd transmitter 21 to the portable device 1 from the RSSI value of the wake signal contained in the response signal.

  Next, the in-vehicle control unit 29 determines that the portable device 1 is in the driver's seat based on the calculated distance from the first transmitter 20 to the portable device 1 and the distance from the second transmitter 21 to the portable device 1. It is determined whether the vehicle is located outside the door, outside the passenger door, or inside the passenger compartment. For example, as shown in FIG. 2, the distance from the first transmitter 20 to the portable device 1 is the distance d10 in the drawing, and the distance from the second transmitter 21 to the portable device 1 is shown in the drawing. When the distance is d20, it can be determined that the portable device 1 is located outside the door of the driver's seat. For example, when the distance from the first transmitter 20 to the portable device 1 is the distance d11 in the drawing and the distance from the second transmitter 21 to the portable device 1 is the distance d21 in the drawing, It can be determined that the portable device 1 is located in the driver's seat. Thus, the position of the portable device 1 can be determined based on the distance from the first transmitter 20 to the portable device 1 and the distance from the second transmitter 21 to the portable device 1. In the present embodiment, the relationship between the distance from the first transmitter 20 to the portable device 1, the distance from the second transmitter 21 to the portable device 1, and the position of the portable device 1 is obtained through experiments and the like. These relationships are stored in the memory 29a of the in-vehicle control unit 29 as a map. The in-vehicle control unit 29 uses the map stored in the memory 29a to determine the portable device based on the distance from the first transmitter 20 to the portable device 1 and the distance from the second transmitter 21 to the portable device 1. The position of 1 is determined.

  The vehicle-mounted control unit 29 locks and unlocks the vehicle door and starts the engine based on the determined position of the portable device 1 and which of the operations (a1) to (a3) is performed. Determine which of these will be done. When the engine switch 23 is pressed down and the portable device 1 is located in the vehicle interior, the in-vehicle control unit 29 is connected to the engine via an in-vehicle network such as a CAN (Controller Area Network). An engine start request is sent to the control unit 28. Thereby, the vehicle-mounted engine is started. Further, when the lock switch 24 is pressed and the portable device 1 is located outside the door of the driver seat or outside the door of the passenger seat, the door lock mechanism 27 is driven. Lock the vehicle door. Further, when the user's hand touches the door knob and the portable device 1 is located outside the door of the driver seat or outside the door of the passenger seat, the door lock mechanism 27 is driven. Unlock the vehicle door.

  By the way, in such an electronic key system of a vehicle, when the spike noise described above is mixed in a wake signal in which the RSSI value is measured in the portable device 1, the position of the portable device 1 may not be appropriately determined. There is. Therefore, in this embodiment, the RSSI value of the wake signal is measured three times in order to eliminate the influence of spike noise, and the remaining two measurement results excluding the one having the highest intensity among those measurement results are measured. The position of the portable device 1 is determined based on the average value. The details will be described below.

  As shown in FIG. 4, the wake signal of the present embodiment has a frame configuration including a burst portion for measuring the RSSI value in the latter half portion shifted by the time width Ta from the head portion. As shown in the figure, the burst portion has a signal level corresponding to the high level only three times at a constant period Tb from the beginning.

  Next, the procedure by which the portable device control unit 13 measures the RSSI value of a wake signal having such a frame configuration will be described with reference to FIG. The process shown in FIG. 5 is executed when the portable device control unit 13 receives a wake signal.

  As shown in FIG. 5, in this process, first, the elapsed time from the time when the wake signal is received via the receiver 10 is measured through the internal timer of the portable device control unit 13 (step S1), and the elapsed time. Is reached three times through the RSSI circuit 12 at a fixed period Tb from the time when the time Ta is reached (step S2). Thereby, as shown in FIG. 5, the RSSI value of the signal level corresponding to the high level of the burst part included in the wake signal is measured three times. Next, an average value of the remaining two RSSI values excluding the largest one among the three measured RSSI values rs1 to rs3 is calculated (step S3), and the average value of the calculated measurement results is calculated as a wake signal. As an RSSI value measurement result, an ACK signal including this is generated and transmitted from the transmitter 11 (step S4).

Next, an operation example (action) of the electronic key system according to the present embodiment will be described with reference to FIG.
Since spike noise is a single noise, when spike noise is mixed in the wake signal, only a part of the entire wake signal is affected. Therefore, even if spike noise is mixed in the wake signal, it is rare that spike noise is mixed in all three places having signal levels corresponding to the high level in the burst portion. Normally, as shown in FIG. , Spike noise will be mixed in one of them. Here, the case where spike noise is mixed in the first portion of the three locations having the signal level corresponding to the high level is illustrated. When such a wake signal is received by the portable device 1, when the RSSI value is measured three times by the portable device control unit 13, the RSSI value rs1 of the measurement result becomes an abnormal value. At this time, in this embodiment, the RSSI value of the wake signal is obtained by calculating the average value of the remaining RSSI values rs2 and rs3 excluding the largest RSSI value rs1 among the three measurement results of the RSSI value. The RSSI value of the wake signal is obtained based on the measurement result with little influence of spike noise. Therefore, the RSSI value of the wake signal can be detected with high accuracy. Thereby, in the vehicle equipment 2, when determining the position of the portable device 1 based on the RSSI value included in the response signal, the position of the portable device 1 can be determined with higher accuracy. The vehicle control according to the position can be appropriately executed. Therefore, malfunction of the electronic key system can be suppressed.

  Further, if the average value of the RSSI value is obtained and the position of the portable device 1 is determined based on the average value, the position of the portable device 1 is determined while suppressing the influence due to the variation in the measurement result. Is possible. Thereby, since the position of the portable device 1 can be determined with higher accuracy, the malfunction of the electronic key system can be more accurately suppressed.

  Furthermore, if it is a method of excluding only one of the three RSSI values measured in the portable device 1, the RSSI value can be set to about three times. The time taken for the measurement does not increase significantly. Thereby, it becomes possible to shorten the communication time between the portable device 1 and the vehicle-mounted device 2 as much as possible.

As described above, according to the electronic key system for a vehicle according to the present embodiment, the following effects can be obtained.
(1) In the portable device 1, the RSSI value of the wake signal is measured three times. Moreover, in the portable device 1, among the three RSSI values rs1 to rs3 to be measured, the average value of the remaining two RSSI values excluding the one with the highest intensity is calculated, and this is set as the RSSI value of the wake signal. It was. On the other hand, the in-vehicle device 2 determines the position of the portable device 1 based on the RSSI value of the wake signal included in the response signal transmitted from the portable device 1. Thereby, since the position of the portable device 1 can be determined with higher accuracy, it is possible to suppress malfunction as the electronic key system.

  (2) In determining the RSSI value of the wake signal, only the strongest of the three RSSI values measured in the portable device 1 is excluded. Thereby, since the frequency | count which measures an RSSI value in the portable device 1 can be set to about three times, it becomes possible to shorten the communication time between the portable device 1 and a vehicle equipment as much as possible.

  (3) The portable device 1 performs the process of calculating the average value of the RSSI values. Thereby, compared with the case where the same process is performed on the in-vehicle device 2 side, the processing burden on the in-vehicle device 2 side can be reduced.

  (4) The first and second transmitters 20 and 21 are provided in the vehicle. The RSSI value measured by the portable device 1 when the wake signal is transmitted from the first transmitter 20 and the RSSI value measured by the portable device 1 when the wake signal is transmitted from the second transmitter 21. Based on both, the position of the portable device 1 is determined, and vehicle control is executed based on the determination result. Thereby, it is possible to suppress malfunction of the electronic key system while reducing the number of transmitters mounted on the vehicle to two.

  (5) The wake signal transmitted from the in-vehicle device 2 is provided with a burst portion for measuring the RSSI value. This eliminates the need to transmit a new signal for measuring the received signal strength from the in-vehicle device 2, so that a new signal different from the wake signal and the request signal is transmitted between the portable device 1 and the in-vehicle device 2. No need to give or receive. Therefore, the communication time between the portable device 1 and the in-vehicle device 2 can be shortened.

In addition, the said embodiment can also be implemented with the following forms which changed this suitably.
In the above embodiment, the first and second transmitters 20 and 21 are provided on the door of the driver seat and the door of the passenger seat, respectively, but the arrangement of each of the first and second transmitters 20 and 21 is provided. Can be appropriately changed.

In the above embodiment, the RSSI value of the wake signal is included in the response signal. However, the RSSI value of the wake signal may be included in the ACK signal.
In the above embodiment, the number of times the RSSI value of the wake signal is measured is set to three in the portable device 1, but the number of RSSI value measurements can be changed as appropriate. For example, when the RSSI value measurement count is set to 4, the average value is calculated by, for example, obtaining the average value of the remaining two measurement results excluding the two measurement results from the measurement result having the highest intensity. In this case, the number of measurement results to be excluded may be changed as appropriate. The point is that the average value of the RSSI values is calculated based on the remaining measurement results excluding a certain number of measurement results from those having a high strength among the plurality of measurement results of the RSSI values measured by the portable device 1. That's fine.

  In the above embodiment, the RSSI value of the wake signal is calculated by calculating the average value of the remaining two measurement results except the one with the highest intensity among the three measurement results of the RSSI value measured by the portable device 1. I decided to ask. Instead of this, for example, one of the remaining two measurement results excluding the one with the highest intensity may be adopted as the RSSI value of the wake signal.

  -By including all data of the three RSSI values measured in the portable device 1 in the response signal and transmitting this from the portable device 1 to the vehicle-mounted device 2, the strongest of the three RSSI values rs1 to rs3 Processing such as calculating the average value of the remaining two RSSI values excluding large ones may be performed on the in-vehicle device 2 side. With such a configuration, it is possible to reduce the processing burden on the portable device 1.

  In the above embodiment, the RSSI value of the wake signal is measured, but instead, for example, the RSSI value of the request signal may be measured. Further, a new signal for RSSI measurement may be transmitted from the first and second transmitters 20 and 21 separately from the wake signal and the request signal, and the RSSI value of the new signal may be measured by the portable device 1. .

  In the above embodiment, the portable device 1 is authenticated through the verification of the identification code stored in the portable device 1 and the identification code stored in the in-vehicle device 2, but instead of this, for example, You may authenticate the portable device 1 by what is called challenge response authentication which authenticates the portable device 1 by exchanging a challenge code between the portable device 1 and the vehicle-mounted device 2.

  In the above embodiment, the vehicle electronic key system according to the present invention is applied to the electronic key system that locks and unlocks the vehicle door and starts the engine based on the position of the portable device 1. Instead of this, for example, the present invention can be applied to an electronic key system that issues some alarm based on the position of the portable device 1. In short, the electronic key system according to the present invention can be applied to any electronic key system for a vehicle that executes predetermined vehicle control based on the position of the portable device 1.

  -In above-mentioned embodiment, applying the electronic key system of the vehicle concerning this invention to the electronic key system which determines the position of the portable device 1 by transmitting a radio signal from two transmitters mounted in the vehicle; did. Instead of this, for example, the position of the portable device 1 is determined by transmitting a wireless signal from one transmitter mounted on the vehicle, or wireless transmitted from three or more transmitters mounted on the vehicle. The present invention can also be applied to an electronic key system that determines the position of the portable device 1 by transmitting a signal. In short, the RSSI value of the radio signal transmitted from the in-vehicle device 2 is measured by the portable device 1, the position of the portable device 1 is determined based on the measurement result, and the vehicle control is executed based on the measurement result. The electronic key system according to the present invention can be applied to any electronic key system for a vehicle.

<Appendix>
Next, a technical idea that can be grasped from the above embodiment and its modifications will be additionally described.
(A) In the electronic key system for a vehicle according to any one of claims 1 to 3, when the portable device measures the received signal strength of the first radio signal a plurality of times, the plurality of measurement results The electronic key system for a vehicle is characterized in that the remaining measurement results excluding a certain number of measurement results from those having high strength are included in the second radio signal and transmitted. As with the same configuration, if processing such as excluding a certain number of measurement results from a plurality of measurement results of received signal strength is performed on the portable device side, the same processing is performed on the in-vehicle device side. Compared with the case where it performs by, it becomes possible to reduce the processing burden by the vehicle equipment side.

  (B) In the electronic key system for a vehicle according to any one of claims 1 to 3 and appendix i, the in-vehicle device is a driver's seat of the vehicle as a transmitter for transmitting the first radio signal. A first transmitter for transmitting the first radio signal to the outer periphery of the door and the vehicle interior; and a second transmitter for transmitting the first radio signal to the outer periphery of the door of the passenger seat of the vehicle and the vehicle interior. And the received signal strength measured by the portable device when the first radio signal is transmitted from the first transmitter, and the first transmitter from the second transmitter. The position of the portable device is determined based on both the received signal strength measured by the portable device when a wireless signal is transmitted, and vehicle control according to the determination result is executed. Vehicle electronic key system. According to this configuration, the malfunction of the electronic key system can be suppressed while the number of transmitters mounted on the in-vehicle device is two.

  (C) In the electronic key system for a vehicle according to any one of claims 1 to 3, appendix i, and appendix b, the portable device is used as a radio signal transmitted from the in-vehicle device to the portable device. A wake signal for activation and a request signal for requesting the portable device to transmit authentication information, wherein the first wireless signal is one of the wake signal and the request signal. The vehicle's electronic key system features. According to this configuration, since the received signal strength measurement by the portable device is performed in the wake signal and the request signal transmitted from the in-vehicle device, a new signal for measuring the received signal strength is transmitted from the in-vehicle device to the portable device. No need to send. This eliminates the need to exchange a new signal different from the wake signal and the request signal between the portable device and the vehicle-mounted device, thereby shortening the communication time between them.

  A1 ... first communication area, A2 ... second communication area, 1 ... mobile device, 2 ... in-vehicle device, 10 ... receiver, 11 ... transmitter, 12 ... RSSI circuit, 13 ... portable device controller, 13a ... Memory 20... First transmitter 21. Second transmitter 22. Receiver 23. Engine switch 24. Lock switch 25. Brake sensor 26. Touch sensor 27 27 Door lock mechanism 28 ... Engine control unit, 29 ... In-vehicle control unit, 29a ... Memory.

Claims (3)

Wireless communication is performed between the in-vehicle device and the portable device on the condition that the portable device is located in a communication area of the in-vehicle device mounted on the vehicle, and the portable device is transmitted from the in-vehicle device. When the first radio signal is received, the received signal strength is measured, and the second radio signal including the measurement result is transmitted to the in-vehicle device, and the in-vehicle device is included in the second radio signal. In an electronic key system for a vehicle that determines a position of the portable device in the communication area based on a measurement result of the received signal strength and executes vehicle control according to the determination result,
The portable device measures the received signal strength of the first wireless signal a plurality of times,
The on-vehicle device determines the position of the portable device based on the remaining measurement results excluding a certain number of measurement results from a plurality of measurement results of received signal strength measured by the portable device. An electronic key system for vehicles characterized by. The vehicle electronic device according to claim 1, wherein the position of the portable device is determined based on an average value of the remaining measurement results obtained by excluding a predetermined number of measurement results from a plurality of measurement results having a high intensity. Key system. The electronic key system for a vehicle according to claim 1, wherein the certain number is set to one.