JP7454399B2 - Communication systems, in-vehicle devices, and programs - Google Patents

Description

The present invention relates to a communication system, an in-vehicle device, and a program.

In Patent Document 1 below, a key drive device (corresponding to a vehicle-mounted device) transmits a challenge signal to a control device (corresponding to a mobile terminal), and in response to this challenge signal, the control device transmits a response signal to the key drive device. A technique for doing so has been disclosed. Further, Patent Document 1 listed below discloses a technology in which a key drive device authenticates a control device based on a response signal received from a control device, and when the authentication is successful, drives an electronic drive key.

JP 2019-188512 Publication

However, when the conventional technology is applied to a communication system where the frequency of transmission of response signals from a mobile terminal is higher than the frequency of transmission of challenge signals from an in-vehicle device, synchronization between the challenge signal and the response signal is lost. There is a possibility.

A communication system according to an embodiment includes a mobile terminal and an in-vehicle device installed in a vehicle and capable of wirelessly communicating with the mobile terminal, and the in-vehicle device transmits a challenge signal to the mobile terminal at regular transmission intervals. The mobile terminal includes a challenge signal receiving section that receives the challenge signal, a response signal calculating section that calculates a response signal based on the challenge signal received by the challenge signal receiving section, and a response signal calculating section that calculates the response signal based on the challenge signal received by the challenge signal receiving section. and a response signal transmitting section that transmits the response signal calculated by the section and the identification information of the challenge signal to the in-vehicle device.

According to one embodiment, the challenge signal and the response signal can be synchronized more reliably.

A diagram showing a system configuration of a communication system according to an embodiment A diagram showing the hardware configuration of an in-vehicle device and a smartphone according to an embodiment A diagram showing the functional configuration of an in-vehicle device and a smartphone according to an embodiment A diagram showing a first example of a communication sequence by a communication system according to an embodiment Flowchart showing the procedure of processing by the in-vehicle device according to one embodiment Flowchart showing the procedure of processing by a smartphone according to an embodiment A diagram showing a second example of a communication sequence by a communication system according to an embodiment Flowchart showing the procedure of processing by the in-vehicle device according to one embodiment Flowchart showing the procedure of processing by a smartphone according to an embodiment A diagram showing an example of remote control using a smartphone according to an embodiment

Hereinafter, one embodiment will be described with reference to the drawings.

(Example of processing by communication system 10)
FIG. 1 is a diagram showing a system configuration of a communication system 10 according to an embodiment. The communication system 10 shown in FIG. 1 includes an on-vehicle device 14 mounted on a vehicle 12 such as a four-wheeled vehicle, and a smartphone 20 (an example of a "mobile terminal") carried by a user such as a driver of the vehicle 12. The in-vehicle device 14 and the smartphone 20 can perform wireless communication with each other using BLE (Bluetooth (registered trademark) Low Energy) using a 2.4 GHz frequency band.

In the communication system 10 shown in FIG. 1, the vehicle 12 can be remotely controlled from the smartphone 20 via the vehicle-mounted device 14 by wirelessly communicating between the vehicle-mounted device 14 and the smartphone 20. For example, the smartphone 20 can remotely control an automatic parking system included in the vehicle 12 via the in-vehicle device 14. During remote control of the automatic parking system, the user performs a predetermined operation on the touch panel 215 using the smartphone 20 according to a display screen for remote control displayed on the display 217.

The in-vehicle device 14 repeatedly transmits a challenge signal and receives a response signal to the smartphone 20 while controlling the automatic parking system. As a result, the in-vehicle device 14 maintains a wireless communication connection with the smartphone 20 and the user performs a predetermined operation on the smartphone 20 as a condition for continuously controlling the automatic parking system. Confirm this repeatedly.

Hereinafter, transmission and reception of a challenge signal and a response signal between the in-vehicle device 14 and the smartphone 20 for performing such confirmation will be described in detail.

(Hardware configuration of in-vehicle device 14 and smartphone 20)
FIG. 2 is a diagram showing the hardware configurations of the in-vehicle device 14 and the smartphone 20 according to one embodiment.

As shown in FIG. 2, the in-vehicle device 14 includes a CPU (Central Processing Unit) 201, a ROM (Read Only Memory) 202, a RAM (Random Access Memory) 203, and a wireless communication module 204. Each piece of hardware is interconnected via a bus 205.

The CPU 201 controls the operation of the in-vehicle device 14 by executing various programs stored in the ROM 202. ROM202 is a nonvolatile memory. For example, the ROM 202 stores programs executed by the CPU 201, data necessary for the CPU 201 to execute the programs, and the like. The RAM 203 is a main storage device such as DRAM (Dynamic Random Access Memory) or SRAM (Static Random Access Memory). For example, the RAM 203 functions as a work area used when the CPU 201 executes a program.

The wireless communication module 204 performs BLE wireless communication with the smartphone 20. The wireless communication module 204 includes a signal processing circuit that performs various signal processing (for example, amplification processing, encoding/decoding processing, AD conversion/DA conversion processing, modulation/demodulation processing, filter processing, etc.), and various signal processing circuits. It is equipped with a communication antenna, etc. that transmits and receives radio waves corresponding to the above.

On the other hand, as shown in FIG. 2, the smartphone 20 includes a CPU 211, a ROM 212, a RAM 213, a wireless communication module 214, a touch panel 215, a battery 216, and a display 217. Each piece of hardware is interconnected via a bus 218.

The CPU 211 controls the operation of the smartphone 20 by executing various programs stored in the ROM 212. ROM 212 is a nonvolatile memory. For example, the ROM 212 stores programs executed by the CPU 211, data necessary for the CPU 211 to execute the programs, and the like. The RAM 213 is a main storage device such as DRAM or SRAM. For example, the RAM 213 functions as a work area used when the CPU 211 executes a program.

The wireless communication module 214 performs BLE wireless communication with the in-vehicle device 14. The wireless communication module 214 includes a signal processing circuit that performs various signal processing (for example, amplification processing, encoding/decoding processing, AD conversion/DA conversion processing, modulation/demodulation processing, filter processing, etc.), and various signal processing circuits. It is equipped with a communication antenna, etc. that transmits and receives radio waves corresponding to the above.

Touch panel 215 and display 217 are provided to be exposed from the surface of the case of smartphone 20. Touch panel 215 accepts various user operations. For example, during remote control of the automatic parking system, the touch panel 215 accepts predetermined operations from the user. Display 217 is provided on the back side of touch panel 215. Display 217 displays various information. For example, during remote control of the automatic parking system, the display 217 displays a predetermined display screen that prompts the user to perform a predetermined operation.

Battery 216 supplies power to each part of smartphone 20. For example, as the battery 216, various rechargeable secondary batteries (eg, lithium ion secondary battery, lithium ion polymer secondary battery, etc.) are used.

(Functional configuration of in-vehicle device 14 and smartphone 20)
FIG. 3 is a diagram showing the functional configurations of the in-vehicle device 14 and the smartphone 20 according to one embodiment.

<Functional configuration of in-vehicle device 14>
As shown in FIG. 3, the in-vehicle device 14 includes a wireless communication section 301, a challenge signal transmission section 302, a response signal reception section 303, a response signal calculation section 304, a determination section 305, and a processing section 306.

The wireless communication unit 301 performs a BLE wireless communication connection with the smartphone 20, and performs BLE wireless communication with the smartphone 20 via the BLE wireless communication connection. The wireless communication unit 301 is realized by the wireless communication module 204 shown in FIG.

During remote control of the vehicle 12 from the smartphone 20, the challenge signal transmission unit 302 transmits a challenge signal and the challenge signal to the smartphone 20 via BLE wireless communication by the wireless communication unit 301 at predetermined transmission intervals. The identification information VAC is transmitted. For example, the challenge signal transmitter 302 connects the challenge signal's identification information VAC to a predetermined position (for example, the beginning position, middle position, end position, etc.) of the challenge signal, and transmits the challenge signal and the identification information VAC of the challenge signal. is sent to the smartphone 20. Note that in this embodiment, the challenge signal transmitter 302 transmits a random number as the challenge signal. Further, in the present embodiment, the challenge signal transmitting unit 302 transmits, as identification information VAC, information that is consecutively numbered so that the challenge signal can be uniquely identified (that is, a serial number).

The response signal receiving unit 303 receives, via BLE wireless communication by the wireless communication unit 301, the response signal transmitted from the smartphone 20 and the identification information VAC of the challenge signal used to generate the response signal.

The response signal calculation unit 304 is an example of a “comparison response signal calculation unit”. The response signal calculation unit 304 acquires the challenge signal corresponding to the identification information VAC received by the response signal reception unit 303 and the key data registered in the vehicle-mounted device 14 in advance from the memory. Then, the response signal calculation unit 304 calculates a comparison response signal based on the challenge signal and key data acquired from the memory. Here, the response signal calculation unit 304 uses the same calculation method and key data as the calculation method (for example, AES-128) and key data used by the smartphone 20, which is a regular device, to generate a comparison response signal. calculate. Therefore, the comparison response signal calculated by the response signal calculation unit 304 is the same as the response signal transmitted from the smartphone 20, which is a regular device.

The determining unit 305 determines whether the comparison response signal calculated by the response signal calculating unit 304 matches the response signal received from the smartphone 20 by the response signal receiving unit 303. Then, when both response signals match, the determining unit 305 determines that the source device of the response signal received by the response signal receiving unit 303 is a legitimate device. On the other hand, if the two response signals do not match, the determining unit 305 determines that the device that is the source of the response signal received by the response signal receiving unit 303 is not a legitimate device.

The processing unit 306 executes processing according to the determination result by the determination unit 305. For example, when the determining unit 305 determines that both response signals match, the processing unit 306 performs processing according to the operation signal of the smartphone 20 attached to the response signal received by the response signal receiving unit 303 (for example, (processing that continues to control the automatic parking system). At this time, the processing unit 306 controls the automatic parking system of the vehicle 12 while detecting that a predetermined user operation is performed on the smartphone 20 based on the operation signal attached to the response signal. Thus, the automatic parking process for the vehicle 12 can be continued. On the other hand, if the determining unit 305 determines that the two response signals do not match, the processing unit 306 performs predetermined error processing (for example, ignoring the operation signal attached to the response signal and not performing any wireless communication). 301).

Note that each function of the in-vehicle device 14 shown in FIG. This is realized by the CPU 201 executing a program stored in the .

<Functional configuration of smartphone 20>
As shown in FIG. 3, the smartphone 20 includes a wireless communication section 311, a challenge signal reception section 312, a response signal calculation section 313, and a response signal transmission section 314.

The wireless communication unit 311 establishes a BLE wireless communication connection with the in-vehicle device 14, and performs BLE wireless communication with the in-vehicle device 14 via the BLE wireless communication connection. The wireless communication unit 311 is realized by the wireless communication module 214 shown in FIG.

The challenge signal receiving unit 312 receives the challenge signal transmitted from the in-vehicle device 14 and the identification information VAC of the challenge signal via the BLE wireless communication by the wireless communication unit 311.

The response signal calculation unit 313 generates a response signal based on the challenge signal received by the challenge signal reception unit 312 and key data registered in the smartphone 20 in advance. For example, the response signal calculation unit 313 calculates the response signal using AES-128, which is a common key encryption algorithm. Further, the response signal calculation unit 313 generates a response signal based on the latest challenge signal (that is, the most recently received challenge signal) at the time of generating the response signal. Note that as the response signal transmitter 314 continuously transmits response signals at predetermined transmission intervals, the response signal calculator 313 continuously generates response signals.

The response signal transmitting unit 314 transmits the response signal generated by the response signal calculating unit 313 to the in-vehicle device 14 via the BLE wireless communication by the wireless communication unit 311 at predetermined transmission intervals. At this time, the response signal transmission unit 314 transmits the identification information VAC of the challenge signal used to generate the response signal to the vehicle-mounted device 14 together with the response signal. Furthermore, the response signal transmitter 314 transmits the operation signal of the smartphone 20 to the in-vehicle device 14 along with the response signal. The operation signal of the smartphone 20 includes, for example, coordinate information representing the user's touch operation position on the touch panel 215 included in the smartphone 20. Note that the response signal transmitter 314 can transmit the response signal to the vehicle-mounted device 14 at a transmission interval shorter than the transmission interval of the challenge signal by the vehicle-mounted device 14. Thereby, the response signal transmission unit 314 can notify the in-vehicle device 14 of a series of user operations on the smartphone 20 (that is, continuous values of coordinate information) without stress.

In addition, each function (challenge signal receiving part 312, response signal calculation part 313, and response signal transmission part 314) of the smartphone 20 shown in FIG. This is achieved by This program may be provided from outside and installed into the smartphone 20. In this case, this program may be provided by an external storage medium (for example, a USB memory, a memory card, a CD-ROM, etc.) or by being downloaded from a server on a network (for example, the Internet, etc.). good.

(First example of processing sequence by communication system 10)
FIG. 4 is a diagram illustrating a first example of a communication sequence by the communication system 10 according to an embodiment. As shown in FIG. 4, the in-vehicle device 14 transmits a challenge signal to the smartphone 20 at regular transmission intervals. On the other hand, as shown in FIG. 4, when there is an operation signal, the smartphone 20 transmits a response signal to the vehicle-mounted device 14 at a shorter transmission interval than the vehicle-mounted device 14.

Here, the smartphone 20 generates a response signal based on the latest challenge signal received from the in-vehicle device 14 and key information registered in the smartphone 20 in advance. In addition, the smartphone 20 transmits identification information VAC corresponding to the challenge signal used to generate the response signal to the in-vehicle device 14 together with the response signal.

Thereby, the in-vehicle device 14 can easily identify which challenge signal the response signal received from the smartphone 20 corresponds to, based on the identification information VAC received together with the response signal.

For example, as shown in FIG. 4, even if the in-vehicle device 14 receives the response signal RESP1-1 corresponding to the previous challenge signal CHAL1 after transmitting the next challenge signal CHAL2, the in-vehicle device 14 transmits the response signal RESP1. -1 corresponds to the previous challenge signal CHAL1, it can be easily identified by the identification information VAC1 received together with the response signal RESP1-1.

(Procedure of processing by in-vehicle device 14)
FIG. 5 is a flowchart showing the procedure of processing by the in-vehicle device 14 according to one embodiment. FIG. 5 shows a processing procedure by the in-vehicle device 14, which corresponds to the first example of the processing sequence shown in FIG.

First, the challenge signal transmitter 302 starts measurement using a timer (step S501).

Next, the in-vehicle device 14 determines whether the BLE wireless communication connection with the smartphone 20 is continued (step S502).

In step S502, if it is determined that the BLE wireless communication connection with the smartphone 20 is not continued (step S502: No), the in-vehicle device 14 ends the series of processes shown in FIG. 5.

On the other hand, if it is determined in step S502 that the BLE wireless communication connection with the smartphone 20 is continued (step S502: Yes), the response signal receiving unit 303 determines whether or not the response signal and the identification information VAC have been received. is determined (step S503).

In step S503, if it is determined that the response signal and the identification information VAC have been received (step S503: Yes), the response signal calculation unit 304 generates a challenge signal corresponding to the identification information VAC received in step S503 and a The key data registered in the device 14 is acquired from the memory (step S504).

Then, the response signal calculation unit 304 calculates a comparison response signal based on the challenge signal and key data acquired in step S504 (step S505).

Further, the determination unit 305 determines whether the comparison response signal calculated in step S505 matches the response signal received in step S503 (step S506).

In step S506, if it is determined that both response signals match (step S506: Yes), the processing unit 306 performs processing according to the operation signal of the smartphone 20 attached to the response signal received in step S503 (for example, , a process of continuously controlling the automatic parking system) is executed (step S507). Then, the in-vehicle device 14 returns the process to step S502.

On the other hand, if it is determined in step S506 that the two response signals do not match (step S506: No), the processing unit 306 executes predetermined error processing (step S508). Then, the in-vehicle device 14 returns the process to step S502.

If it is determined in step S503 that the response signal and the identification information VAC have not been received (step S503: No), the challenge signal transmitter 302 determines whether a certain period of time has elapsed since the start of measurement by the timer. (Step S509).

In step S509, if it is determined that a certain period of time has elapsed (step S509: Yes), the challenge signal transmitting unit 302 transmits the challenge signal and the identification information VAC of the challenge signal to the smartphone 20 (step S510). ). Then, the challenge signal transmitting unit 302 clears the measurement by the timer (step S511). After that, the in-vehicle device 14 returns the process to step S502.

On the other hand, if it is determined in step S509 that the certain period of time has not elapsed (step S509: Yes), the in-vehicle device 14 returns the process to step S502.

(Procedure of processing by smartphone 20)
FIG. 6 is a flowchart showing the procedure of processing by the smartphone 20 according to one embodiment. FIG. 6 shows a processing procedure by the smartphone 20 corresponding to the first example of the processing sequence shown in FIG. 4.

First, the smartphone 20 determines whether the BLE wireless communication connection with the in-vehicle device 14 is continued (step S601).

In step S601, if it is determined that the BLE wireless communication connection with the in-vehicle device 14 is not continued (step S601: No), the smartphone 20 ends the series of processes shown in FIG. 6.

On the other hand, if it is determined in step S601 that the BLE wireless communication connection with the in-vehicle device 14 is continued (step S601: Yes), the challenge signal receiving unit 312 determines whether or not it has received the challenge and the identification information VAC. is determined (step S602).

If it is determined in step S602 that the challenge signal and identification information VAC have been received (step S602: Yes), the challenge signal receiving unit 312 stores the challenge signal and identification information VAC received in step S602 in memory ( Step S606). The smartphone 20 then returns the process to step S601.

On the other hand, if it is determined in step S602 that the challenge signal and identification information VAC have not been received (step S602: No), the response signal transmitter 314 determines whether there is an operation signal that needs to be transmitted to the in-vehicle device 14. It is determined whether or not (step S603).

In step S603, if it is determined that there is no operation signal that needs to be transmitted to the in-vehicle device 14 (step S603: No), the smartphone 20 returns the process to step S601.

On the other hand, if it is determined in step S603 that there is an operation signal that needs to be transmitted to the in-vehicle device 14 (step S603: Yes), the response signal calculation unit 313 uses the challenge signal received in step S602 and the smartphone in advance. A response signal is calculated based on the key data registered in 20 (step S604).

Then, the response signal transmission unit 314 transmits the response signal calculated in step S604 and the identification information VAC of the challenge signal used to generate the response signal to the in-vehicle device 14 (step S605). After that, the smartphone 20 returns the process to step S601.

(Second example of processing sequence by communication system 10)
FIG. 7 is a diagram illustrating a second example of a communication sequence by the communication system 10 according to an embodiment. As shown in FIG. 7, the in-vehicle device 14 transmits a challenge signal to the smartphone 20 at regular transmission intervals. On the other hand, as shown in FIG. 7, when there is an operation signal, the smartphone 20 transmits a response signal to the vehicle-mounted device 14 at a shorter transmission interval than the vehicle-mounted device 14.

Here, the smartphone 20 generates a response signal based on the latest challenge signal received from the in-vehicle device 14, key information registered in the smartphone 20 in advance, and identification information SAC of the response signal to be generated. . In addition, the smartphone 20 transmits, together with the response signal, identification information VAC corresponding to the challenge signal used to generate the response signal and identification information SAC used to generate the response signal to the in-vehicle device 14. .

Thereby, the in-vehicle device 14 can easily identify which challenge signal the response signal received from the smartphone 20 corresponds to, based on the identification information VAC received together with the response signal.

For example, as shown in FIG. 7, even if the in-vehicle device 14 receives the response signal RESP1-1 corresponding to the previous challenge signal CHAL1 after transmitting the next challenge signal CHAL2, the in-vehicle device 14 transmits the response signal RESP1. -1 corresponds to the previous challenge signal CHAL1 can be easily identified by the identification information VAC1 received together with the response signal RESP1-1.

Furthermore, even when generating and transmitting a plurality of response signals corresponding to the same challenge signal, the smartphone 20 can generate and transmit a plurality of response signals by assigning a different SAC to each of the plurality of response signals. The security strength of each can be increased.

For example, as shown in FIG. 7, even when the smartphone 20 generates and transmits two response signals RESP1 and RESP1-1 corresponding to the same challenge signal CHAL1, the smartphone 20 generates and transmits two response signals RESP1 and RESP1-1. By assigning different SACs (SAC1, SAC2) to each of the two response signals RESP1 and RESP1-1, the security strength of each of the two response signals RESP1 and RESP1-1 can be increased.

Further, even when the in-vehicle device 14 receives a plurality of response signals corresponding to the same challenge signal, it can distinguish each of the plurality of response signals by the individually assigned SAC.

For example, as shown in FIG. 7, even if the in-vehicle device 14 receives two response signals RESP1 and RESP1-1 corresponding to the same challenge signal CHAL1, Each of these can be distinguished by an individually assigned SAC (SAC1, SAC2).

(Procedure of processing by in-vehicle device 14)
FIG. 8 is a flowchart showing the procedure of processing by the in-vehicle device 14 according to one embodiment. FIG. 8 shows a processing procedure by the in-vehicle device 14 corresponding to the second example of the processing sequence shown in FIG.

First, the challenge signal transmitter 302 starts measurement using a timer (step S801).

Next, the in-vehicle device 14 determines whether the BLE wireless communication connection with the smartphone 20 is continued (step S802).

In step S802, if it is determined that the BLE wireless communication connection with the smartphone 20 is not continued (step S802: No), the in-vehicle device 14 ends the series of processes shown in FIG. 8.

On the other hand, if it is determined in step S802 that the BLE wireless communication connection with the smartphone 20 is continued (step S802: Yes), the response signal receiving unit 303 receives the response signal, the identification information VAC, and the identification information SAC. It is determined whether or not it has been received (step S803).

If it is determined in step S803 that the response signal, identification information VAC, and identification information SAC have been received (step S803: Yes), the response signal calculation unit 304 calculates a challenge corresponding to the identification information VAC received in step S803. The signal and key data registered in advance in the vehicle-mounted device 14 are acquired from the memory (step S804).

Then, the response signal calculation unit 304 calculates a comparison response signal based on the challenge signal and key data acquired in step S804 and the identification information SAC received in step S803 (step S805).

Further, the determination unit 305 determines whether the comparison response signal calculated in step S805 matches the response signal received in step S803 (step S806).

In step S806, if it is determined that both response signals match (step S806: Yes), the processing unit 306 performs processing according to the operation signal of the smartphone 20 attached to the response signal received in step S803 (for example, , a process of continuously controlling the automatic parking system) is executed (step S807). Then, the in-vehicle device 14 returns the process to step S802.

On the other hand, if it is determined in step S806 that the two response signals do not match (step S806: No), the processing unit 306 executes predetermined error processing (step S808). Then, the in-vehicle device 14 returns the process to step S802.

If it is determined in step S803 that the response signal, identification information VAC, and identification information SAC have not been received (step S803: No), the challenge signal transmitter 302 determines whether a certain period of time has elapsed since the start of measurement by the timer. It is determined whether or not (step S809).

In step S809, if it is determined that a certain period of time has elapsed (step S809: Yes), the challenge signal transmitting unit 302 transmits the challenge signal and the identification information VAC of the challenge signal to the smartphone 20 (step S810). ). Then, the challenge signal transmitting unit 302 clears the measurement by the timer (step S811). After that, the in-vehicle device 14 returns the process to step S802.

On the other hand, if it is determined in step S809 that the certain period of time has not elapsed (step S809: Yes), the in-vehicle device 14 returns the process to step S802.

(Procedure of processing by smartphone 20)
FIG. 9 is a flowchart showing the procedure of processing by the smartphone 20 according to one embodiment. FIG. 9 shows a processing procedure by the smartphone 20 corresponding to the second example of the processing sequence shown in FIG. 7.

First, the smartphone 20 determines whether the BLE wireless communication connection with the in-vehicle device 14 is continued (step S901).

In step S901, if it is determined that the BLE wireless communication connection with the in-vehicle device 14 is not continued (step S901: No), the smartphone 20 ends the series of processes shown in FIG. 9.

On the other hand, if it is determined in step S901 that the BLE wireless communication connection with the in-vehicle device 14 is continued (step S901: Yes), the challenge signal receiving unit 312 determines whether or not the challenge and identification information VAC have been received. is determined (step S902).

If it is determined in step S902 that the challenge signal and identification information VAC have been received (step S902: Yes), the challenge signal receiving unit 312 stores the challenge signal and identification information VAC received in step S902 in memory ( Step S907). The smartphone 20 then returns the process to step S901.

On the other hand, if it is determined in step S902 that the challenge signal and the identification information VAC have not been received (step S902: No), the response signal transmitter 314 determines whether there is an operation signal that needs to be transmitted to the in-vehicle device 14. It is determined whether or not (step S903).

In step S903, if it is determined that there is no operation signal that needs to be transmitted to the in-vehicle device 14 (step S903: No), the smartphone 20 returns the process to step S901.

On the other hand, if it is determined in step S903 that there is an operation signal that needs to be transmitted to the in-vehicle device 14 (step S903: Yes), the response signal calculation unit 313 calculates the challenge signal received in step S902 and the smartphone in advance. A response signal is calculated based on the key data registered in 20 and the identification information SAC given to the generated response signal (step S904).

Then, the response signal transmission unit 314 transmits the response signal calculated in step S904, the identification information VAC of the challenge signal used to generate the response signal, and the identification information SAC used to generate the response signal. , is transmitted to the in-vehicle device 14 (step S905).

Furthermore, the response signal calculation unit 313 determines the next generated identification information SAC by adding 1 to the number part of the identification information SAC used to generate the response signal (step S906). returns the process to step S901.

(Example of remote control using smartphone 20)
FIG. 10 is a diagram illustrating an example of remote operation using the smartphone 20 according to an embodiment. In the example shown in FIG. 10, a display screen 1000 for remote control of the automatic parking system of the vehicle 12 is displayed on the display 217 of the smartphone 20. This display screen 1000 is displayed on the display 217 by executing an application for remote control of the automatic parking system installed in the smartphone 20.

As shown in FIG. 10, a display screen 1000 displays an annular object 1002 and an arrow figure 1004 along the circumference of the object 1002. The arrow shape 1004 prompts the user to trace the finger clockwise along the circumference of the object 1002.

When the user performs an operation of tracing a finger on the operation surface of the touch panel 215 in accordance with the arrow diagram 1004, the smartphone 20 sends a response to the in-vehicle device 14 at a fixed transmission interval while this operation is performed. Send signals continuously. At this time, the smartphone 20 transmits an operation signal representing the contact position of the user's finger on the touch panel 215 to the vehicle-mounted device 14 along with the response signal. Each time the in-vehicle device 14 receives a response signal, if it determines that the smartphone 20 is a legitimate device, it continues to control the automatic parking system in accordance with the operation signal attached to the response signal.

As described above, the communication system 10 according to one embodiment includes the smartphone 20 and the in-vehicle device 14 that is mounted on the vehicle 12 and is capable of wirelessly communicating with the smartphone 20. The smartphone 20 includes a challenge signal transmitting section 302 that transmits a challenge signal to the smartphone 20 at transmission intervals, and a challenge signal receiving section 312 that receives the challenge signal, and a response based on the challenge signal received by the challenge signal receiving section 312. It includes a response signal calculation section 313 that calculates a signal, and a response signal transmission section 314 that transmits the response signal calculated by the response signal calculation section 313 and identification information VAC of the challenge signal to the in-vehicle device 14.

Thereby, in the communication system 10 according to one embodiment, the in-vehicle device 14 can identify which challenge signal it has transmitted to which the response signal received from the smartphone 20 corresponds, along with the response signal received. It can be easily identified by the information VAC. Therefore, according to the communication system 10 according to one embodiment, the challenge signal and the response signal can be synchronized more reliably.

Further, in the communication system 10 according to one embodiment, the challenge signal transmitting unit 302 transmits the identification information VAC of the challenge signal together with the challenge signal to the smartphone 20, and the response signal transmitting unit 314 calculates the identification information VAC by the response signal calculating unit 313. The received response signal and the identification information VAC of the challenge signal received by the challenge signal receiving section 312 are transmitted to the on-vehicle device 14.

Thereby, in the communication system 10 according to one embodiment, the in-vehicle device 14 can more reliably specify which challenge signal transmitted by the in-vehicle device 14 corresponds to the response signal received from the smartphone 20. can.

Furthermore, in the communication system 10 according to one embodiment, the identification information VAC is a serial number.

Thereby, the communication system 10 according to one embodiment can easily generate the identification information VAC. Moreover, the communication system 10 according to one embodiment can easily specify the transmission order relationship of a plurality of challenge signals using the identification information VAC.

In the communication system 10 according to one embodiment, the challenge signal transmission unit 302 connects the challenge signal identification information VAC to a predetermined position of the challenge signal, and transmits the challenge signal and the identification information VAC of the challenge signal to the smartphone 20. can be sent to.

Thereby, the communication system 10 according to one embodiment can make it difficult for a third party who does not know the format of the challenge signal and the identification information VAC to analyze the data. Therefore, according to the communication system 10 according to one embodiment, the confidentiality of the challenge signal can be improved.

In the communication system 10 according to one embodiment, the response signal calculation unit 313 calculates a response signal based on the challenge signal received by the challenge signal reception unit 312 and the identification information SAC of the response signal, and The transmitter 314 transmits the response signal calculated by the response signal calculator 313, the challenge signal identification information VAC, and the response signal identification information SAC to the in-vehicle device 14.

Thereby, even if the smartphone 20 transmits a plurality of responses to one challenge signal, the communication system 10 according to one embodiment can make each response signal different from each other, so that each response signal Confidentiality can be improved.

In the communication system 10 according to one embodiment, the in-vehicle device 14 based on the challenge signal corresponding to the identification information VAC of the challenge signal received from the smartphone 20 and the identification information SAC of the response signal received from the smartphone 20. , a response signal calculation unit 304 that calculates a comparison response signal, and a determination unit 305 that determines whether the response signal received from the smartphone 20 and the comparison response signal calculated by the response signal calculation unit 304 match. It further includes:

As a result, in the communication system 10 according to one embodiment, even if the smartphone 20 transmits multiple responses to one challenge signal, the in-vehicle device 14 transmits a legitimate response signal to each of the multiple response signals. It is possible to determine whether the message was sent from a device.

Furthermore, in the communication system 10 according to one embodiment, the response signal transmitter 314 attaches the operation signal of the smartphone 20 to the response signal and transmits the response signal to the vehicle-mounted device 14.

Thereby, the communication system 10 according to one embodiment can synchronize the response signal with the operation signal attached to the challenge signal. Therefore, the communication system 10 according to one embodiment can improve the reliability of the operation signal received by the in-vehicle device 14.

Furthermore, in the communication system 10 according to one embodiment, the operation signal attached to the response signal includes coordinate information representing the user's touch operation position on the touch panel 215 included in the smartphone 20.

Thereby, the communication system 10 according to one embodiment continuously transmits response signals from the smartphone 20 at short transmission intervals in order to notify the in-vehicle device 14 of a series of user operations (that is, continuous values of coordinate information) without stress. Therefore, the usefulness of the synchronization processing performed by the communication system 10 can be increased.

Further, in the communication system 10 according to one embodiment, while the in-vehicle device 14 detects that a predetermined user operation is performed on the smartphone 20 based on the operation signal attached to the response signal, , the automatic parking system included in the vehicle 12 includes a processing unit 306 that causes the automatic parking process of the vehicle 12 to continue.

As a result, the communication system 10 according to one embodiment needs to continuously transmit response signals from the smartphone 20 at short transmission intervals in order to continue automatic parking processing of the vehicle 12 without stress. The usefulness of the synchronization process performed by the communication system 10 can be increased.

Further, the communication system 10 according to one embodiment uses BLE (Bluetooth Low Energy) for wireless communication between the in-vehicle device 14 and the smartphone 20.

Thereby, the communication system 10 according to one embodiment can realize low power consumption of wireless communication between the in-vehicle device 14 and the smartphone 20.

Although one embodiment of the present invention has been described in detail above, the present invention is not limited to these embodiments, and various modifications or variations can be made within the scope of the gist of the present invention as described in the claims. Changes are possible.

For example, the communication system 10 according to one embodiment may use the reception time when the smartphone 20 receives the challenge signal from the in-vehicle device 14 as the identification information VAC of the challenge signal. In this case, the in-vehicle device 14 does not need to transmit the identification information VAC of the challenge signal.

For example, the communication system 10 according to one embodiment may use randomly generated identification information VAC of the challenge signal. In this case, the communication system 10 according to one embodiment can improve the confidentiality of the challenge signal identification information VAC rather than using a serial number as the challenge signal identification information VAC.

10 Communication system 12 Vehicle 14 In-vehicle device 20 Smartphone (mobile terminal)
215 Touch panel 217 Display 301 Wireless communication section 302 Challenge signal transmission section 303 Response signal reception section 304 Response signal calculation section (comparison response signal calculation section)
305 Judgment unit 306 Processing unit 311 Wireless communication unit 312 Challenge signal reception unit 313 Response signal calculation unit 314 Response signal transmission unit SAC Response signal identification information VAC Challenge signal identification information

Claims (17)

A mobile device and
an in-vehicle device installed in a vehicle and capable of wirelessly communicating with the mobile terminal;
The in-vehicle device includes:
comprising a challenge signal transmitter that transmits a challenge signal to the mobile terminal at fixed transmission intervals,
The mobile terminal is
a challenge signal receiving section that receives the challenge signal;
a response signal calculation unit that calculates a response signal based on the challenge signal received by the challenge signal reception unit;
comprising a response signal transmitting section that transmits the response signal calculated by the response signal calculating section and identification information of the challenge signal to the in-vehicle device ,
While the mobile terminal is being operated, the response signal transmitter transmits a response signal at a transmission interval shorter than a transmission interval at which the in-vehicle device transmits a challenge signal,
When the challenge signal receiving unit receives the challenge signal and the identification information of the challenge signal, storing the received challenge signal and the identification information of the challenge signal in a memory,
The response signal calculation unit calculates the challenge signal stored in the memory while the mobile terminal is being operated, when the challenge signal reception unit has not received the challenge signal and the identification information of the challenge signal. and a response signal based on pre-stored key data, and the response signal transmitter transmits the calculated response signal and identification information of a challenge signal used to generate the response signal to the in-vehicle device. do
A communication system characterized by: The challenge signal transmitter includes:
transmitting identification information of the challenge signal together with the challenge signal to the mobile terminal;
The response signal transmitter includes:
transmitting the response signal calculated by the response signal calculation unit and identification information of the challenge signal received by the challenge signal reception unit to the in-vehicle device;
The response signal is calculated based on the challenge signal and pre-stored key data,
The identification information of the challenge signal transmitted by the challenge signal transmission section is the same as the identification information of the challenge signal transmitted by the response signal transmission section.
The communication system according to claim 1, characterized in that: The communication system according to claim 2, wherein the identification information of the challenge signal is a serial number. The communication system according to claim 2, wherein the identification information of the challenge signal is randomly generated information. The challenge signal transmitter includes:
Any one of claims 2 to 4, wherein identification information of the challenge signal is connected to a predetermined position of the challenge signal, and the challenge signal and the identification information of the challenge signal are transmitted to the mobile terminal. The communication system described in . The communication system according to claim 1, wherein the identification information of the challenge signal is a reception time of the challenge signal by the challenge signal receiving section. The response signal calculation section is
Calculating a response signal based on the challenge signal received by the challenge signal receiving unit and identification information of the response signal,
The response signal transmitter includes:
Any one of claims 1 to 4 , wherein the response signal calculated by the response signal calculation unit, identification information of the challenge signal, and identification information of the response signal are transmitted to the in-vehicle device. The communication system according to paragraph 1. The in-vehicle device includes:
a comparison response signal calculation unit that calculates a comparison response signal based on the challenge signal corresponding to identification information of the challenge signal received from the mobile terminal and identification information of the response signal received from the mobile terminal; and,
Claim further comprising: a determination unit that determines whether the response signal received from the mobile terminal and the comparison response signal calculated by the comparison response signal calculation unit match. 7. The communication system according to 7. The mobile terminal is a smartphone,
The response signal transmitter includes:
The communication system according to any one of claims 1 to 4 , wherein an operation signal of the smartphone is attached to the response signal and transmitted to the in-vehicle device. The operation signal includes coordinate information representing a user's touch operation position with respect to a touch panel included in the smartphone,
The response signal transmitting unit transmits the response signal at regular transmission intervals while the user's finger is moving on the operation surface of the touch panel.
The communication system according to claim 9, characterized in that: The in-vehicle device includes:
A processing unit that causes an automatic parking system included in the vehicle to continue automatic parking processing for the vehicle while detecting that a predetermined user operation is performed on the smartphone based on the operation signal. The communication system according to claim 10, comprising: The communication system according to any one of claims 1 to 4 , wherein BLE (Bluetooth Low Energy) is used for the wireless communication. A program for a mobile terminal that can perform wireless communication with an in-vehicle device installed in a vehicle,
computer,
a challenge signal receiving unit that receives a challenge signal transmitted from the in- vehicle device at regular transmission intervals;
a response signal calculation unit that calculates a response signal based on the challenge signal received by the challenge signal reception unit, and
A program for functioning as a response signal transmission unit that transmits the response signal calculated by the response signal calculation unit and identification information of the challenge signal to the in-vehicle device ,
While the mobile terminal is being operated, the response signal transmitter transmits a response signal at a transmission interval shorter than a transmission interval at which the in-vehicle device transmits a challenge signal,
When the challenge signal receiving unit receives the challenge signal and the identification information of the challenge signal, storing the received challenge signal and the identification information of the challenge signal in a memory,
The response signal calculation unit calculates the challenge signal stored in the memory while the mobile terminal is being operated, when the challenge signal reception unit has not received the challenge signal and the identification information of the challenge signal. and a response signal based on pre-stored key data, and the response signal transmitter transmits the calculated response signal and identification information of a challenge signal used to generate the response signal to the in-vehicle device. do
program. A mobile device and
an in-vehicle device installed in a vehicle and capable of wirelessly communicating with the mobile terminal;
Equipped with
The in-vehicle device includes:
comprising a challenge signal transmitter that transmits a challenge signal to the mobile terminal at fixed transmission intervals,
The mobile terminal is
a challenge signal receiving section that receives the challenge signal;
a response signal calculation unit that calculates a response signal based on the challenge signal received by the challenge signal reception unit;
a response signal transmitting unit configured to transmit the response signal calculated by the response signal calculating unit and identification information of the challenge signal to the in-vehicle device;
The challenge signal transmitter includes:
transmitting identification information of the challenge signal together with the challenge signal to the mobile terminal;
The response signal transmitter includes:
transmitting the response signal calculated by the response signal calculation unit and identification information of the challenge signal received by the challenge signal reception unit to the in-vehicle device;
The identification information of the challenge signal is randomly generated information.
A communication system characterized by: A mobile device and
an in-vehicle device installed in a vehicle and capable of wirelessly communicating with the mobile terminal;
Equipped with
The in-vehicle device includes:
comprising a challenge signal transmitter that transmits a challenge signal to the mobile terminal at fixed transmission intervals,
The mobile terminal is
a challenge signal receiving section that receives the challenge signal;
a response signal calculation unit that calculates a response signal based on the challenge signal received by the challenge signal reception unit;
a response signal transmitting unit configured to transmit the response signal calculated by the response signal calculating unit and identification information of the challenge signal to the in-vehicle device;
The identification information of the challenge signal is a reception time of the challenge signal by the challenge signal receiving section.
A communication system characterized by: A mobile device and
an in-vehicle device installed in a vehicle and capable of wirelessly communicating with the mobile terminal;
Equipped with
The in-vehicle device includes:
comprising a challenge signal transmitter that transmits a challenge signal to the mobile terminal at fixed transmission intervals,
The mobile terminal is
a challenge signal receiving section that receives the challenge signal;
a response signal calculation unit that calculates a response signal based on the challenge signal received by the challenge signal reception unit;
a response signal transmitting unit configured to transmit the response signal calculated by the response signal calculating unit and identification information of the challenge signal to the in-vehicle device;
The response signal calculation unit includes:
Calculating a response signal based on the challenge signal received by the challenge signal receiving unit and identification information of the response signal,
The response signal transmitter includes:
transmitting the response signal calculated by the response signal calculation unit, identification information of the challenge signal, and identification information of the response signal to the in-vehicle device;
A communication system characterized by: A mobile device and
an in-vehicle device installed in a vehicle and capable of wirelessly communicating with the mobile terminal;
Equipped with
The in-vehicle device includes:
comprising a challenge signal transmitter that transmits a challenge signal to the mobile terminal at fixed transmission intervals,
The mobile terminal is
a challenge signal receiving section that receives the challenge signal;
a response signal calculation unit that calculates a response signal based on the challenge signal received by the challenge signal reception unit;
a response signal transmitting unit configured to transmit the response signal calculated by the response signal calculating unit and identification information of the challenge signal to the in-vehicle device;
The mobile terminal is a smartphone,
The response signal transmitter includes:
transmitting an operation signal of the smartphone to the in-vehicle device along with the response signal;
The operation signal is a user's touch operation on a touch panel included in the smartphone.
Contains coordinate information representing the location,
The in-vehicle device includes:
A processing unit that causes an automatic parking system included in the vehicle to continue automatic parking processing for the vehicle while detecting that a predetermined user operation is performed on the smartphone based on the operation signal. equipped with
A communication system characterized by:

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