JP4585961B2 - Wireless communication control system - Google Patents

Description

  The present invention relates to a wireless communication control system used in, for example, a vehicle or a house.

  In recent years, for example, in automobiles, improvement in convenience as well as improvement in basic performance and safety has been demanded. Therefore, for the purpose of improving the convenience, conventionally, wireless communication is automatically performed between the portable device possessed by the user and the vehicle-mounted device (communication control device), and the wireless communication is established. There has been proposed a communication control system that automatically locks and unlocks a door lock and makes it possible to start an engine (see, for example, Patent Document 1).

Specifically, the in-vehicle device intermittently transmits a preset wireless signal (request signal) around the vehicle or in the vehicle compartment. When the portable device enters the request signal transmission area, the portable device receives the request signal and returns an ID code signal including the ID code set to itself in response to the request signal. When the in-vehicle device receives this ID code signal, it checks the ID code set in itself and the ID code included in the ID code signal, and communication with the portable device is established when the ID codes match. It is judged that the vehicle has been closed, and vehicle control is performed such as unlocking the door lock and enabling the engine to start. That is, mutual communication is automatically performed between the in-vehicle device and the portable device, and vehicle control is performed on the condition that the mutual communication is established. For this reason, the user can suitably control the vehicle without performing an operation using a machine key or the like, and the operability of the vehicle is improved. In addition, since the electrical verification is a condition for vehicle control, the security level of the vehicle is also improved.
JP 2001-31333 A

  However, in such a communication control system, since wireless communication is performed between the portable device and the communication control device, a communication failure may occur if there is noise that affects the communication between the two. . For example, when noise having the same frequency as the ID code signal transmitted from the portable device exists around the communication control device, the communication control device receives the noise. Therefore, even if the ID code signal is transmitted from the portable device, the noise and the ID code signal are mixed with each other, so that the ID code signal cannot be normally received. Therefore, there is still room for improvement from this viewpoint.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a wireless communication control system capable of suitably performing communication even when noise exists in a communication area.

In order to solve the above-mentioned problem, in the invention according to claim 1, communication control for controlling a portable device that transmits a radio signal and a corresponding device based on the radio signal by receiving the radio signal. A communication control apparatus comprising: a device-side receiving unit capable of selectively receiving radio waves of a plurality of types of frequencies; and a frequency receivable by the device-side receiving unit. When a radio wave different from the radio signal from the portable device is received by the apparatus side receiving means and the apparatus side receiving means capable of transmitting transmission signals set to different frequencies, the reception frequency of the apparatus side receiving means is set. And frequency control for transmitting the transmission signal including the frequency command code for transmitting the radio signal from the portable device at the changed frequency from the device-side transmission unit. And the portable device receives the transmission signal including the frequency command code and portable device-side transmission means capable of transmitting the radio signal at a plurality of types of frequencies that can be received by the device-side reception means. And a frequency setting means for setting the frequency of the radio signal transmitted from the portable device-side transmitting means to a frequency based on the frequency command code, and the communication control is performed on a plurality of channels each assigned a different frequency. And setting the channel in the portable device, the frequency control means sets the reception frequency of the device-side receiving means based on one of the channels, and the device-side receiving means When a radio wave different from the radio signal from the portable device is received by the mobile device, the reception frequency of the device-side receiving means is based on another channel. The transmission signal including the channel command indicating the changed channel as the frequency command code is transmitted from the device-side transmission unit, and the frequency setting unit receives the transmission signal, thereby changing the frequency to the frequency. The frequency of the radio signal is set to the frequency assigned to the channel indicated by the channel code, and the frequency control means is the radio signal from the portable device at all the frequencies assigned to the plurality of channels. When a different radio wave is received, the transmission signal including the notification code is transmitted from the device-side transmission unit, and the frequency setting unit is notified based on the notification code when receiving the transmission signal including the notification code. The gist is to perform control .

  According to the above configuration, when a radio wave different from the radio signal from the portable device is received by the device-side receiving means, the frequency control means changes the reception frequency of the device-side receiving means, and the changed frequency is A transmission signal including the indicated frequency command code is transmitted from the apparatus-side transmission means. When the transmission signal is received by the portable device, the frequency of the radio signal transmitted from the portable device is set based on the frequency command code. For this reason, even if radio waves (noise) different from the radio signal from the portable device exist around the device-side receiving means, the reception frequency of the device-side receiving means and the frequency of the radio signal are different from the noise. Will be set. Therefore, the noise is suppressed from interfering with the radio signal, and suitable communication between the portable device and the communication control device becomes possible.

Further, the reception frequency of the apparatus side receiving means and the frequency of the radio signal are set based on a plurality of preset channels. Since these channels are set in common for the communication control device and the portable device, it is possible to reliably match the reception frequency of the device-side receiving means with the frequency of the radio signal. In addition, since a code for specifying a channel may be included in the transmission signal, the amount of information of the transmission signal can be reduced.

Furthermore, when there is noise of all frequencies assigned to the plurality of channels, a transmission signal including a notification code is transmitted from the communication control device. And a portable machine will alert | report that by receiving the transmission signal. That is, the portable device notifies that the apparatus-side receiving unit is in a state where it cannot normally receive a radio signal from the portable device. For this reason, the user who possesses the portable device can surely recognize that by the notification, and does not mistakenly recognize that the portable device or the communication control device is out of order.

As described above in detail, according to the present invention, it is possible to provide a wireless communication control system capable of performing communication appropriately even when noise exists in the communication area.

(First embodiment)
Hereinafter, a first embodiment in which a wireless communication control system of the present invention is embodied as a vehicle communication control system will be described in detail with reference to FIGS.

  As shown in FIGS. 1 and 2, the vehicle communication control system is possessed by a communication control device 10 having a wireless communication function disposed in the vehicle 1 and the owner (user) of the vehicle 1, A portable device 20 capable of wireless communication with the communication control device 10 is provided.

<Configuration of Communication Control Device 10>
As shown in FIG. 1, the communication control device 10 is electrically connected to a device-side microcomputer (device-side microcomputer) 11 constituted by a computer unit composed of a CPU, ROM, RAM, etc., and the device-side microcomputer 11 respectively. The apparatus side transmitting circuit 12 as the apparatus side transmitting means and the apparatus side receiving circuit 13 as the apparatus side receiving means are provided.

  The device-side transmission circuit 12 is configured to be able to transmit radio waves in a predetermined frequency band (here, LF band (for example, 124 kHz)). When a transmission request signal (request signal) is input from the device-side microcomputer 11, the device-side transmission circuit 12 modulates the request signal into a radio wave and transmits the request signal to the outside with a preset intermittent period and output intensity. . As shown in FIG. 2, in the present embodiment, the device-side transmission circuit 12 selectively transmits a request signal to the vehicle exterior area A1 around the door of the vehicle 1 and the indoor area A2 of the vehicle 1.

  The device-side receiving circuit 13 is configured to be able to selectively receive a plurality of types of radio waves among radio waves in a predetermined frequency band (here, UHF band). Specifically, the device-side receiving circuit 13 changes the reception frequency based on the frequency control signal input from the device-side microcomputer 11. That is, the reception frequency of the device side receiving circuit 13 is variably controlled by the device side microcomputer 11. When receiving the radio wave, the device-side receiving circuit 13 demodulates the radio wave into a pulse signal and outputs it to the device-side microcomputer 11.

  The device-side microcomputer 11 is electrically connected to a start switch 14, a door lock device 15 as a device to be controlled, and an engine control device 16 provided in the vehicle 1. The start switch 14 is configured by a push button switch or the like disposed in the vicinity of the driver's seat (for example, a dashboard or a steering column) in the passenger compartment, and an operation signal thereof is input to the apparatus-side microcomputer 11. The door lock device 15 is a device that automatically locks and unlocks the door lock. When the unlock signal is input from the device-side microcomputer 11, the door lock device 15 is unlocked, and when the lock signal is input, the door lock is unlocked. Lock. Further, the door lock device 15 outputs a lock / unlock state signal indicating the lock / unlock state of the door lock to the device-side microcomputer 11. The engine control device 16 is connected to a cell motor (not shown). When a drive signal is input from the device-side microcomputer 11, the engine control device 16 drives the cell motor to automatically start the engine and outputs an engine status signal indicating the engine drive status. Output to the device-side microcomputer 11. Therefore, the device-side microcomputer 11 can recognize the door lock locking / unlocking state and the engine driving state based on the locking / unlocking state signal and the engine state signal.

  Such a device-side microcomputer 11 includes a nonvolatile memory 11a. The memory 11a includes a plurality of unique request codes, an ID code set in the corresponding portable device 20, and a reception frequency of the device-side receiving circuit 13. And a preset notification code are recorded. Each channel is associated with a different frequency. Specifically, as shown in FIG. 3, in this embodiment, three channels 1 to 3 are recorded in the memory 11a, and the channel 1 has a frequency of 300 MHz, the channel 2 has a frequency of 312 MHz, and the channel 3 has a frequency of 324 MHz. It is associated.

  The device-side microcomputer 11 sets the reception frequency of the device-side reception circuit 13 and transmits a request signal from the device-side transmission circuit 12 so that a response signal (ID code signal) is transmitted from the portable device 20 at the reception frequency. Perform frequency control. Therefore, the apparatus side microcomputer 11 functions as a frequency control means. The apparatus-side microcomputer 11 is configured to alternatively transmit a request signal from the apparatus-side transmission circuit 12 to the vehicle exterior area A1 and the indoor area A2.

  Further, when the device side receiving circuit 13 receives the ID code signal transmitted from the portable device 20 in response to the request signal, the device side microcomputer 11 receives the ID code included in the ID code signal and the memory 11a. (ID code collation) with the recorded ID code, and various vehicle controls (door lock control, engine start permission) are performed based on the result. Specifically, when the ID code signal transmitted in response to the request signal transmitted to the vehicle exterior area A1 is received by the device-side receiving circuit 13, the device-side microcomputer 11 sends an unlock signal to the door lock device 15. Output to unlock the door lock. The device-side microcomputer 11 outputs a lock signal to the door lock device 15 to lock the door lock when a lock switch provided on an outdoor handle (not shown) is operated in such an unlocked state of the door lock. It is supposed to let you. The apparatus-side microcomputer 11 enters the engine start permission state when the ID code signal transmitted in response to the request signal transmitted to the indoor area A2 is received by the apparatus side reception circuit 13, and starts in the engine start permission state. When an operation signal is input from the switch 14, a drive signal is output to the engine control device 16 to start the engine. In other words, the device-side microcomputer 11 does not output a drive signal to the engine control device 16 even if an operation signal is input from the start switch 14 unless the engine start permission state is entered.

<Processing of apparatus side microcomputer 11>
Next, processing (frequency control processing and vehicle control processing) performed by the device-side microcomputer 11 of the communication control device 10 in the vehicle communication control system configured as described above will be described with reference to the flowchart shown in FIG.

  As shown in the figure, in step S1, the apparatus-side microcomputer 11 sets the reception frequency of the apparatus-side receiving circuit 13 by performing channel setting. Specifically, the device-side microcomputer 11 outputs a frequency control signal to the device-side receiving circuit 13 so that the frequency (300 MHz) associated with the channel 1 is set to the reception frequency of the device-side receiving circuit 13 in the initial state. Therefore, the device-side receiving circuit 13 can receive a 300 MHz radio wave based on the frequency control signal. Here, the “initial state” indicates a state where there is no channel setting history, for example, when the vehicle communication control system is shipped from the factory. When the channel setting history is not in the “initial state”, that is, the device side microcomputer 11 sets the frequency associated with the latest history channel to the reception frequency of the device side receiving circuit 13. A frequency control signal is output to the device-side receiving circuit 13. For this reason, for example, when channel 1 was previously set, channel 1 is continuously set.

  In subsequent step S2, the apparatus-side microcomputer 11 determines whether or not radio waves are received by the apparatus-side receiving circuit 13 based on the reception frequency based on the channel set in step S1. Specifically, for example, when channel 1 is set in step S1, the device-side microcomputer 11 sets the reception frequency of the device-side receiving circuit 13 to 300 MHz, and the 300-MHz radio wave is received by the device-side receiving circuit 13. It is judged whether it was done. As a result, when it is determined that no radio wave is received by the device-side receiving circuit 13, the device-side microcomputer 11 proceeds to the process of step S3, and receives a request signal including the channel code set in step S1 as a frequency command code. Transmission is performed from the device-side transmission circuit 12 to the outside.

  In step S4, the device-side microcomputer 11 determines whether or not the ID code signal transmitted from the portable device 20 has been received in response to the request signal transmitted in step S3. That is, in step S4, the apparatus-side microcomputer 11 determines whether or not a radio wave including an ID code that matches the ID code recorded in the memory 11a is received within a predetermined time after the transmission of the request signal. As a result, when the apparatus side microcomputer 11 cannot receive the ID code signal, the process here is temporarily terminated. On the other hand, the apparatus side microcomputer 11 performs various vehicle control corresponding in step S5, when an ID code signal can be received. Specifically, the apparatus-side microcomputer 11 performs door lock control when receiving an ID code signal in response to the request signal transmitted to the vehicle exterior area A1, automatically unlocks the door lock, and transmits it to the indoor area A2. When the ID code signal in response to the request signal is received, the engine start permission state is set.

  On the other hand, when a radio wave is received by the apparatus side receiving circuit 13 in step S2, the apparatus side microcomputer 11 proceeds to the process of step S6, and whether or not the ID code recorded in the memory 11a is included in the radio wave. Judging. As a result, if the device-side microcomputer 11 determines that the ID code is included, the device-side microcomputer 11 determines that the locking / unlocking operation signal has been transmitted from the portable device 20 and proceeds to the process of step S7 to control the door lock. I do. Specifically, the device-side microcomputer 11 outputs a locking signal or unlocking signal to the door locking device 15 based on the locking code included in the locking / unlocking operation signal, and locks or unlocks the door lock, The process here is temporarily terminated.

  If the apparatus-side microcomputer 11 determines in step S6 that the ID code recorded in the memory 11a is not included in the received radio wave, the apparatus-side microcomputer 11 determines that the radio wave is noise and proceeds to the process in step S8. Transition.

  In step S8, the apparatus-side microcomputer 11 determines whether noise has been received in all channels 1 to 3. That is, the device-side microcomputer 11 determines whether noise has been received at all frequencies corresponding to the reception frequencies of the device-side receiving circuit 13 corresponding to the channels 1 to 3, respectively. As a result, if the apparatus-side microcomputer 11 determines that no noise is received in all the channels 1 to 3, the apparatus-side microcomputer 11 proceeds to the process of step S9 and changes the channel. Specifically, the device-side microcomputer 11 changes to channel 2 if channel 1 is set in step S1, for example, changes to channel 3 if it is set to channel 2, and changes to channel 3 If set, change to channel 1. For this reason, the reception frequency of the apparatus side receiving circuit 13 will be changed with the change of each channel 1-3. And the apparatus side microcomputer 11 transfers to the process of step S2 again. On the other hand, if it is determined in step S8 that noise has been received in all the channels 1 to 3, the apparatus-side microcomputer 11 proceeds to the process of step S10 and sends a request signal including a notification code from the apparatus-side transmission circuit 12. The process here is temporarily terminated.

<Configuration of portable device 20>
On the other hand, as shown in FIG. 1, the portable device 20 includes a portable device side microcomputer (portable device side microcomputer) 21 configured by a computer unit including a CPU, a ROM, a RAM, and the like, and a portable device side microcomputer 21 respectively. An electrically connected portable device side receiving circuit 22 and a portable device side transmitting circuit 23 as a portable device side transmitting means are provided.

  The portable device side receiving circuit 22 is configured to be able to receive radio waves having the same frequency as the request signal. Then, when receiving the radio wave, the portable device side receiving circuit 22 demodulates the radio wave into a pulse signal and outputs it to the portable device side microcomputer 21.

  The portable device side transmission circuit 23 is configured to be able to transmit radio waves at the same frequency that can be received by the device side reception circuit 13. That is, the portable device side transmission circuit 23 can transmit radio waves at the frequencies indicated by the channels 1 to 3. The portable device side transmission circuit 23 sets a transmission frequency based on a frequency setting signal input from the portable device side microcomputer 21, and an ID code signal and a locking / unlocking operation signal are input from the portable device side microcomputer 21. Then, these signals are modulated into radio waves (radio signals) having a set frequency and transmitted to the outside.

  The portable device-side microcomputer 21 includes a non-volatile memory 21a in which the request code, a unique ID code, the plurality of channels 1 to 3 and the notification code are recorded.

  The portable device side microcomputer 21 is electrically provided with a locking / unlocking switch 24 provided on the design surface and operable by a user, and an alarm device 25 including an acoustic device such as a buzzer and a display device such as an LED. It is connected. The locking / unlocking switch 24 includes a locking switch and an unlocking switch (not shown). When the locking switch is operated, a locking operation signal is input to the portable device-side microcomputer 21. When the unlocking switch is operated, the unlocking operation is performed. The signal is input to the portable device side microcomputer 21.

  When the portable device side microcomputer 21 receives the request signal from the corresponding communication control device 10 by the portable device side receiving circuit 22, the portable device side microcomputer 21 sends the frequency setting signal to the portable device side transmission circuit according to the channel code included in the request signal. To 23. For this reason, the transmission frequency of the portable device side transmission circuit 23 changes based on the frequency setting signal. Therefore, the portable device side microcomputer 21 functions as a frequency setting means for setting the transmission frequency of the portable device side transmission circuit 23.

  Further, the portable device side microcomputer 21 outputs an ID code signal including the ID code recorded in the memory 21 a to the portable device side transmission circuit 23. In addition, when a locking operation signal or an unlocking operation signal is input from the locking / unlocking switch 24, the portable device-side microcomputer 21 generates an ID code and a locking code or an unlocking code regardless of whether a request signal is received. The included locking / unlocking operation signal is output to the portable device side transmission circuit 23.

  Furthermore, when the request signal including the notification code is input from the portable device side receiving circuit 22, the portable device side microcomputer 21 outputs an operation signal to the notification device 25 to operate the notification device 25.

<Processing of the portable device side microcomputer 21>
Next, processing (frequency setting processing) performed by the portable device side microcomputer 21 will be described with reference to a flowchart shown in FIG.

  First, in step S <b> 11, the portable device-side microcomputer 21 determines whether the portable device-side receiving circuit 22 has received a request signal from the communication control device 10. That is, the portable device side microcomputer 21 determines whether or not the radio wave received by the portable device side receiving circuit 22 includes the request code recorded in the memory 21a. As a result, when it is determined that the corresponding request signal is not received, the portable device side microcomputer 21 terminates the processing here, and when it is determined that the corresponding request signal is received, the process proceeds to step S12. Transition.

  In step S <b> 12, the portable device side microcomputer 21 determines whether or not a notification code is included in the request signal. As a result, when it is determined that the notification code is not included, the portable device-side microcomputer 21 outputs a frequency setting signal to the portable device-side transmission circuit 23 in step S13, thereby the portable device-side transmission circuit 23. Is set to a frequency based on the channel code included in the request signal. In step S14, the portable device-side microcomputer 21 causes the portable device-side transmission circuit 23 to transmit an ID code signal including the ID code recorded in the memory 21a.

On the other hand, when it is determined in step S12 that the notification code is included in the request signal, the portable device-side microcomputer 21 proceeds to the processing in step S15 and performs notification processing (notification control). That is, the portable device microcomputer 21 actuates the該報knowledge 25 outputs an actuation signal to the alarm 25. By such an operation of the alarm device 25, the user can surely recognize that it is in a situation where normal communication cannot be performed between the portable device 20 and the communication control device 10.

Therefore, according to the present embodiment, the following effects can be obtained.
(1) When a radio wave (noise) different from a radio signal (ID code signal or locking / unlocking operation signal) from the portable device 20 is received by the device-side receiving circuit 13, the device-side microcomputer 11 causes the device-side receiving circuit 13 to And a request signal including a channel code indicating the changed frequency is transmitted from the apparatus-side transmission circuit 12. When the request signal is received by the portable device 20, the transmission frequency of the radio signal transmitted from the portable device 20 is set based on the channel code. Therefore, a radio signal is transmitted from the portable device 20 at a frequency different from noise. That is, even if noise exists around the device-side receiving circuit 13, the reception frequency of the device-side receiving circuit 13 and the frequency of the radio signal are set to frequencies different from the noise. Therefore, the noise is suppressed from interfering with the radio signal, and suitable communication between the portable device 20 and the communication control device 10 becomes possible.

  (2) The reception frequency of the device-side reception circuit 13 and the frequency of the radio signal from the portable device 20 are set based on a plurality of preset channels 1 to 3. Since these channels 1 to 3 are set in common in the communication control device 10 and the portable device 20, the reception frequency of the device-side receiving circuit 13 and the frequency of the wireless signal from the portable device 20 must be matched with each other. Can do. Further, since the request signal only needs to include a code (channel code) for specifying the channels 1 to 3, the information of the request signal is compared with the case where the information for specifying the frequency is included in the request signal. Less amount is required.

  (3) When noise of all frequencies that can be received by the device-side receiving circuit 13 exists in the vicinity, a request signal including a notification code is transmitted from the communication control device 10. When the portable device 20 receives the request signal, the portable device 20 notifies the fact by operating the notification device 25. That is, the portable device 20 notifies that the device-side receiving circuit 13 is in a state where the wireless signal from the portable device 20 cannot be normally received. For this reason, the user who possesses the portable device 20 can surely recognize that fact by the notification, and does not mistakenly recognize that the portable device 20 or the communication control device 10 is out of order.

(Second Embodiment)
Next, a second embodiment (reference example) embodying the present invention will be described with reference to FIGS. Here, points different from the first embodiment will be mainly described, and common points will be simply denoted by the same member numbers, and description thereof will be omitted.

<Outline of vehicle communication control system>
In the first embodiment, the communication control device 10 includes a device-side reception circuit 13 that can be changed to a plurality of types of reception frequencies. The device-side microcomputer 11 changes the reception frequency of the device-side reception circuit 13 and By changing the transmission frequency of the ID code signal from 20, the interference between the ID code signal and noise is prevented. On the other hand, the present embodiment is different from the first embodiment in that it is configured to prevent interference between the request signal and noise by changing the transmission frequency of the request signal.

With this change, as shown in FIG. 6, in this embodiment, the communication control apparatus 10 includes a device-side transmission / reception circuit 17 as a device-side second reception unit and a device-side transmission unit instead of the device-side transmission circuit 12. And a device-side receiving circuit 18 as a device-side first receiving means instead of the device-side receiving circuit 13. The portable device 20 includes a portable device-side receiving circuit 26 as a portable device-side receiving means instead of the portable device-side receiving circuit 22, and a portable device-side transmitting means instead of the portable device-side transmitting circuit 23. The portable device side transmission circuit 27 is provided.

<Configuration of Communication Control Device 10>
The device-side transmission / reception circuit 17 is configured to be able to selectively transmit and receive radio waves of a plurality of types of radio waves among radio waves in a predetermined frequency band (here, LF band). Specifically, the device-side transmission / reception circuit 17 changes the transmission / reception frequency based on a frequency control signal input from the device-side microcomputer 11. That is, the transmission / reception frequency of the device-side transmission / reception circuit 17 is variably controlled by the device-side microcomputer 11. And the apparatus side transmission / reception circuit 17 will demodulate and output to the apparatus side microcomputer 11, if the electromagnetic wave is received with the frequency based on the frequency control signal input from the apparatus side microcomputer 11. When a request signal is input from the apparatus-side microcomputer 11, the request signal is modulated into a radio wave having a frequency set based on the frequency control signal, and transmitted to the outside at a preset intermittent period and output intensity. As shown in FIG. 2, in the present embodiment, the device-side transmission / reception circuit 17 selectively transmits a request signal to the outside area A1 around the door of the vehicle 1 and the indoor area A2 of the vehicle 1.

  The device-side receiving circuit 18 is configured to be able to receive radio waves in a predetermined frequency band (here, UHF band (for example, 312 MHz)) set in advance. That is, the device-side receiving circuit 18 in the present embodiment can receive radio waves of one type of frequency. When receiving the radio wave, the device-side receiving circuit 18 demodulates the radio wave into a pulse signal and outputs it to the device-side microcomputer 11.

  In the memory 11 a of the device-side microcomputer 11, a unique request code, an ID code set in the corresponding portable device 20, and a plurality of channels indicating transmission / reception frequencies of the device-side transmission / reception circuit 17 are recorded. Each channel is associated with a different frequency. Specifically, as shown in FIG. 7, in the present embodiment, three channels 1 to 3 are recorded in the memory 11a, and the channel 1 has a frequency of 112 kHz, the channel 2 has a frequency of 124 kHz, and the channel 3 has a frequency of 136 kHz. It is associated.

  The device-side microcomputer 11 performs frequency control processing for setting the transmission / reception frequency of the device-side transmission / reception circuit 17. Therefore, processing (frequency control processing and vehicle control processing) performed by the apparatus-side microcomputer 11 will be described with reference to the flowchart shown in FIG.

<Processing of apparatus side microcomputer 11>
As shown in the figure, in step S21, the apparatus-side microcomputer 11 sets the transmission / reception frequency of the apparatus-side transmission / reception circuit 17 by performing channel setting. Specifically, the device-side microcomputer 11 outputs a frequency control signal to the device-side transmission / reception circuit 17 so that the frequency (112 kHz) associated with the channel 1 is set to the reception frequency of the device-side transmission / reception circuit 17 in the initial state. For this reason, the device-side transmitting / receiving circuit 17 can receive a 112 kHz radio wave based on the frequency control signal. Here, the “initial state” indicates a state where there is no channel setting history, for example, when the vehicle communication control system is shipped from the factory. If the channel setting history is not in the “initial state”, that is, the device-side microcomputer 11 sets the frequency associated with the latest history channel to the transmission / reception frequency of the device-side transmission / reception circuit 17. A frequency control signal is output to the device-side transmitting / receiving circuit 17. For this reason, for example, when channel 1 was previously set, channel 1 is continuously set. Therefore, in the present embodiment, the device-side microcomputer 11 functions as a frequency control unit that sets the transmission / reception frequency of the device-side transmission / reception circuit 17.

  In subsequent step S22, the apparatus-side microcomputer 11 determines whether or not radio waves have been received by the apparatus-side transmitting / receiving circuit 17 based on the reception frequency based on the channel set in step S21. Specifically, for example, when channel 1 is set in step S21, the apparatus-side microcomputer 11 sets the reception frequency of the apparatus-side transmission / reception circuit 17 to 112 kHz, and the apparatus-side transmission / reception circuit 17 receives the 112 kHz radio wave. It is judged whether it was done. As a result, when it is determined that the radio wave is not received by the device-side transmission / reception circuit 17, the device-side microcomputer 11 proceeds to the process of step S23, and the request signal including the request code is transmitted from the device-side transmission / reception circuit 17 to the outside. Send it. In the present embodiment, the apparatus-side microcomputer 11 transmits a request signal at the intermittent period ΔT shown in FIG. 10, and performs the process of step S22 when the request signal is not transmitted. That is, the apparatus-side microcomputer 11 performs the process of step S22 immediately before transmitting the request signal.

  In step S24, the device-side microcomputer 11 determines whether the device-side receiving circuit 18 has received the ID code signal transmitted from the portable device 20 in response to the request signal transmitted in step S23. That is, in step S24, the apparatus-side microcomputer 11 determines whether or not a radio wave including an ID code that matches the ID code recorded in the memory 11a has been received within a predetermined time after the transmission of the request signal. As a result, when the apparatus side microcomputer 11 cannot receive the ID code signal, the process here is temporarily terminated, and when the ID code signal can be received, various vehicle controls (door lock control, Perform engine start permission control).

  On the other hand, when a radio wave is received by the device-side transmitting / receiving circuit 17 in step S22, the device-side microcomputer 11 proceeds to the process of step S26, and whether or not the ID code recorded in the memory 11a is included in the radio wave. Judging. As a result, if the device-side microcomputer 11 determines that the ID code is included, the device-side microcomputer 11 determines that the locking / unlocking operation signal has been transmitted from the portable device 20 and proceeds to the processing of step S27 to control the door lock. I do. Specifically, the device-side microcomputer 11 outputs a locking signal or unlocking signal to the door locking device 15 based on the locking code included in the locking / unlocking operation signal, and locks or unlocks the door lock, The process here is temporarily terminated.

  If the apparatus-side microcomputer 11 determines in step S26 that the ID code recorded in the memory 11a is not included in the received radio wave, the apparatus-side microcomputer 11 determines that the radio wave is noise and proceeds to the process of step S28. Migrate and change channels. Specifically, for example, the device-side microcomputer 11 changes to channel 2 when channel 1 is set in step S21, changes to channel 3 when channel 2 is set, and is set to channel 3. If so, change to channel 1. For this reason, the transmission / reception frequency of the apparatus side transmission / reception circuit 17 is changed with the change of each channel 1-3. And the apparatus side microcomputer 11 transfers to the process of step S22 again. Therefore, by performing such processing, the apparatus-side microcomputer 11 can transmit a request signal at a frequency different from noise.

<Configuration of portable device 20>
On the other hand, as shown in FIG. 6, the portable device-side receiving circuit 26 of the portable device 20 is configured to be able to receive radio waves having the same frequency as the request signal. That is, the portable device side receiving circuit 26 is configured to be able to receive radio waves at the frequencies indicated by the channels 1 to 3. The portable device-side receiving circuit 26 can set a reception frequency based on a frequency setting signal input from the portable device-side microcomputer 21. When a corresponding radio wave is received, the portable radio device side receiving circuit 26 demodulates the radio wave into a pulse signal and carries it. It outputs to the machine side microcomputer 21.

  The portable device side transmission circuit 27 is configured to be able to transmit radio waves at the same frequency that can be received by the device side reception circuit 13. When an ID code signal or a locking / unlocking operation signal is input from the portable device side microcomputer 21, the portable device side transmission circuit 27 modulates these signals into a radio wave having a set frequency and transmits the signal to the outside. .

The request code, the unique ID code, and the plurality of channels 1 to 3 shown in FIG. 7 are recorded in the memory 21 a of the portable device side microcomputer 21.
Moreover, although the lock / unlock switch 24 provided on the design surface and operable by the user is electrically connected to the portable device side microcomputer 21, the alarm device 25 in the first embodiment is electrically connected. It has no structure. That is, in this embodiment, the portable device 20 does not include the alarm device 25.

  And the portable device side microcomputer 21 outputs a frequency setting signal to the portable device side receiving circuit 26 at a preset cycle. As shown in FIG. 10, in the present embodiment, the portable device side microcomputer 21 is set to output a frequency setting signal every time T that is three times the intermittent period ΔT of the request signal. . For this reason, the portable device side receiving circuit 26 can be changed to a different receiving frequency every time T. In the present embodiment, the portable device side microcomputer 21 is set so as to be sequentially switched to channels 1 to 3 every time T in a state where the request signal is not received by the portable device side receiving circuit 26.

  The portable device side microcomputer 21 outputs the ID code signal to the portable device side transmission circuit 27 when the portable device side reception circuit 26 receives the request signal from the corresponding communication control device 10.

  Therefore, the portable device-side microcomputer 21 functions as a transmission control unit that performs transmission control of the ID code signal based on whether or not the request signal is received by the portable device-side reception circuit 26, and sets the reception frequency of the portable device-side reception circuit 26. It functions as a frequency setting means that is alternatively set.

  In addition, when a locking operation signal or an unlocking operation signal is input from the locking / unlocking switch 24, the portable device-side microcomputer 21 generates an ID code and a locking code or an unlocking code regardless of whether a request signal is received. The included locking / unlocking operation signal is output to the portable device side transmission circuit 23.

<Processing of the portable device side microcomputer 21>
Next, processing (frequency setting processing) performed by the portable device side microcomputer 21 will be described with reference to a flowchart shown in FIG.

  First, in step S31, the portable device side microcomputer 21 sets the reception frequency of the portable device side receiving circuit 26 by performing channel setting. Specifically, the portable device-side microcomputer 21 sends a frequency setting signal to the portable device side receiving circuit 26 so that the frequency (112 kHz) associated with the channel 1 in the initial state is the reception frequency of the portable device side receiving circuit 26. Output. Therefore, the portable device side receiving circuit 26 can receive a 112 kHz radio wave based on the frequency setting signal.

  In subsequent step S <b> 32, the portable device side microcomputer 21 determines whether or not the portable device side receiving circuit 22 has received the request signal from the communication control device 10. That is, the portable device side microcomputer 21 determines whether or not the radio wave having the set frequency is received by the portable device side reception circuit 22 and the request code recorded in the memory 21a is included in the radio wave. As a result, when it is determined that the corresponding request signal has been received, the portable device-side microcomputer 21 proceeds to the process of step S33.

  In step S33, the portable device-side microcomputer 21 transmits an ID code signal including the ID code recorded in the memory 21a from the portable device-side transmission circuit 23, and temporarily ends the processing here.

  On the other hand, if it is determined in step S32 that the corresponding request signal cannot be received by the portable device-side receiving circuit 26, the portable device-side microcomputer 21 proceeds to the process of step S34 and determines whether or not the time T has elapsed. to decide. As a result, when it is determined that the time T has not elapsed, the portable device-side microcomputer 21 proceeds to the process of step S32 again. On the other hand, when it is determined that the time T has elapsed, the portable device-side microcomputer 21 proceeds to the process of step S35 and changes the channel. Specifically, the portable device-side microcomputer 21 changes to channel 2 when channel 1 is set in step S31, for example, and changes to channel 3 when channel 1 is set. If it is set to channel 1, change to channel 1. For this reason, the reception frequency of the portable device side reception circuit 26 is changed at least every time T with the change of each channel 1 to 3. And the apparatus side microcomputer 11 transfers to the process of step S32 again.

Therefore, according to this embodiment, in addition to the effects described in the above (1) to (3) in the first embodiment, the following effects can be obtained.
(4) When radio waves (noise) existing in the vicinity are received by the device-side transmitting / receiving circuit 17, the frequency of the request signal is set to a frequency different from the noise. For this reason, it is suppressed that the noise interferes (interference) with the request signal, and the portable device 20 can reliably receive and recognize the request signal. Therefore, suitable communication between the portable device 20 and the communication control device 10 becomes possible.

  (5) Since the reception frequency of the mobile device side receiving circuit 26 is changed by the mobile device side microcomputer 21 at a preset period (time T), the frequency of the request signal transmitted from the communication control device 10 is changed. Even in such a case, the request signal can be reliably received by the portable device-side receiving circuit 26.

  In addition, since the period (time T) at which the reception frequency of the portable device-side receiving circuit 26 is changed is set to three times the transmission period of the request signal (intermittent period ΔT), the transmission frequency of the request signal Even if the value is changed every intermittent period ΔT, the portable device side receiving circuit 26 can reliably receive the request signal.

In addition, you may change embodiment of this invention as follows.
In the first embodiment, the portable device 20 is provided with the notification device 25, and the notification device 25 is activated when a request signal including a notification code is received by the portable device-side reception circuit 22. ing. However, such an alarm 25 may be omitted. In this way, since it is not necessary to provide the notification device 25 in the portable device 20, the structure of the portable device 20 can be simplified, and it is not necessary to include a notification code in the request signal. The processing of the machine side microcomputer 21 can be simplified.

  In the first embodiment, the communication control device 10 may include a plurality of (for example, three) device-side reception circuits 13 that are set to different reception frequencies. Then, the device-side microcomputer 11 activates one of the device-side receiving circuits 13 in which no noise is received, and a channel corresponding to the frequency of the device-side receiving circuit 13 in the active state. A request signal including a code may be transmitted from the device-side transmission circuit 12.

  In the first embodiment, when the device-side microcomputer 11 receives a radio wave by the device-side receiving circuit 13, the device-side microcomputer 11 determines that the radio wave is less than a preset reception intensity as noise. Also good. In the second embodiment, when the device-side microcomputer 11 receives a radio wave by the device-side transmission / reception circuit 17, the device-side microcomputer 11 determines that the radio wave is noise when the radio wave is below a preset reception intensity. May be. That is, the apparatus-side microcomputer 11 may determine that noise has been received when the received radio wave does not have a predetermined radio wave intensity.

  In the second embodiment, the time T during which the reception frequency of the mobile device side receiving circuit 26 is changed is not limited to a time that is three times the intermittent period ΔT of the request signal. For example, the time T may be set to a time twice as long as the intermittent period ΔT of the request signal when there are two types of reception frequencies of the portable device side reception circuit 26 (when there are two channels). When there are four types of reception frequencies (when there are four channels), the reception frequency may be set to four times the intermittent period ΔT. That is, the time T may be set to a time obtained by multiplying the intermittent period ΔT of the request signal by the number of channels.

In the second embodiment, the communication control device 10 includes the device-side transmitting / receiving circuit 17 as the device-side second receiving unit and the device-side transmitting unit, but can receive a radio wave having the same frequency as the request signal. A circuit and a transmission circuit capable of transmitting the request signal may be provided separately so that the reception circuit functions as a device-side second reception unit and the transmission circuit functions as a device-side transmission unit.

  In each of the above embodiments, the number of channels recorded in the memory 11a of the device-side microcomputer 11 and the memory 21a of the portable device-side microcomputer 21 is not limited to three, and may be two or four or more, for example.

  In each of the above embodiments, the locking / unlocking switch 24 provided in the portable device 20 may be omitted. In this way, the structure of the portable device 20 can be simplified. In addition, the portable device side microcomputer 21 does not need to perform the process of transmitting the locking / unlocking operation signal, and the apparatus side microcomputer 11 does not need to perform door lock control based on the locking / unlocking operation signal. For this reason, the processing burden of both the microcomputers 11 and 21 can be reduced.

  The communication control device 10 is configured to have both the ID code signal reception frequency changing function shown in the first embodiment and the request signal transmission frequency changing function shown in the second embodiment. Alternatively, the portable device 20 may have a configuration similar to this.

The wireless communication control system is not limited to the vehicle communication control system, and may be embodied as a building communication control system that locks and unlocks a door lock of a house or the like by wireless communication.
Next, in addition to the technical ideas described in the claims, the technical ideas grasped by the embodiment described above are listed below.

(1) In the radio communications control system, said frequency control means, when receiving the radio wave below a preset reception strength by the device-side reception unit differs from the radio wave is a radio signal from the portable device Judge that it is a radio wave. According to the technical idea described in (1), it is possible to easily and quickly determine whether or not the received radio wave is a radio wave from a portable device.

  (2) A communication control device that controls a corresponding device based on a wireless signal by receiving a wireless signal transmitted from a portable device having a wireless communication function, and selectively selects radio waves having a plurality of types of frequencies. Device-side receiving means capable of receiving the device, device-side transmitting means capable of transmitting a transmission signal set to a frequency different from the frequency receivable by the device-side receiving means, and the device-side receiving means from the portable device. The transmission including a frequency command code for changing the reception frequency of the device-side receiving unit and transmitting the radio signal from the portable device at the changed frequency when a radio wave different from the radio signal is received. Frequency control means for transmitting a signal from the apparatus-side transmission means.

  (3) A portable device that controls the operation of the corresponding communication control device by transmitting a wireless signal, and is capable of transmitting the wireless signal at a plurality of types of frequencies that can be received by the communication control device. By receiving a transmission signal including a frequency command code transmitted from the transmission control device and the communication control device, the frequency of the radio signal transmitted from the portable device side transmission unit is set to a frequency based on the frequency command code. And a frequency setting means.

  (4) A communication control device that controls a corresponding device based on the wireless signal by receiving a wireless signal transmitted from the portable device having a wireless communication function, and receives the wireless signal from the portable device A device-side first receiving unit capable of transmitting a transmission request signal for requesting the portable device to transmit the radio signal, at a plurality of types of frequencies different from the radio signal; A device-side second receiving unit capable of receiving a radio wave having a frequency that can be transmitted by the transmitting unit; and when the device-side second receiving unit receives a radio wave, the frequency of the transmission request signal is set to the frequency of the radio wave. And frequency control means for setting to different frequencies.

The block diagram which shows schematic structure of the communication control system for vehicles of 1st Embodiment of this invention. The schematic diagram which shows roughly the transmission area | region of the transmission request signal in the vehicle provided with the communication control apparatus of the embodiment. The table | surface which shows the variable frequency of the embodiment. The flowchart which shows the process performed by the frequency control means of the communication control apparatus of the embodiment. The flowchart which shows the process performed by the frequency setting means of the portable device of the embodiment. The block diagram which shows schematic structure of the communication control system for vehicles of 2nd Embodiment. The table | surface which shows the variable frequency of the embodiment. The flowchart which shows the process performed by the frequency control means of the communication control apparatus of the embodiment. The flowchart which shows the process performed by the frequency setting means of the portable device of the embodiment. The graph which shows the relationship between the transmission period of the transmission request signal of the embodiment, and the transmission time of the transmission frequency of a portable device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Communication control apparatus, 11 ... Apparatus side microcomputer (apparatus side microcomputer) as frequency control means, 12 ... Apparatus side transmission circuit as apparatus side transmission means, 13, 18 ... Apparatus side reception means and apparatus side 1st reception Device side reception circuit as means, 17... Device side transmission means and device side transmission / reception circuit as device side second reception means, 20... Portable device, 21... Portable device side microcomputer as frequency setting means and transmission control means ( Portable device side microcomputer), 22, 26... Portable device side receiving circuit as portable device side receiving means, 23, 27... Portable device side transmitting circuit as portable device side transmitting means.

Claims (1)

A wireless communication control system comprising: a portable device that transmits a wireless signal; and a communication control device that controls a corresponding device based on the wireless signal by receiving the wireless signal,
The communication control device includes a device-side receiving unit capable of selectively receiving radio waves of a plurality of types of frequencies, and a device capable of transmitting a transmission signal set to a frequency different from the frequency receivable by the device-side receiving unit When a radio wave different from the radio signal from the portable device is received by the side transmission unit and the device side reception unit, the reception frequency of the device side reception unit is changed, and the radio signal is changed at the changed frequency. A frequency control means for transmitting the transmission signal including a frequency command code for transmission from the portable device from the apparatus-side transmission means;
The portable device receives the transmission signal including the frequency command code and portable device-side transmission means capable of transmitting the wireless signal at a plurality of types of frequencies that can be received by the device-side reception means. Frequency setting means for setting the frequency of the radio signal transmitted from the machine-side transmission means to a frequency based on the frequency command code ,
A plurality of channels assigned with different frequencies are set in the communication control device, and the channels are also set in the portable device.
The frequency control unit sets the reception frequency of the device-side receiving unit based on one of the channels, and when the device-side receiving unit receives a radio wave different from the radio signal from the portable device. The device-side receiving means changes the receiving frequency to a frequency based on another channel, and causes the device-side transmitting means to transmit the transmission signal including a channel code indicating the changed channel as the frequency command code. ,
The frequency setting means sets the frequency of the radio signal to the frequency assigned to the channel indicated by the channel code by receiving the transmission signal,
When the frequency control unit receives radio waves different from the radio signal from the portable device at all frequencies assigned to the plurality of channels, the frequency control unit transmits the transmission signal including a notification code from the device-side transmission unit. Send
The wireless communication control system , wherein the frequency setting means performs notification control based on the notification code when the transmission signal including the notification code is received .

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