KR102654164B1 - Method, system and program for controlling vehicle based on virtual code for authentication - Google Patents

Abstract

Vehicle control methods, systems, and programs based on virtual codes for authentication are provided. The system is an application installed on the terminal of a user using a car rental service. When a control request for the door of the vehicle is received from the application, the system performs verification of the control request and opens the door of the vehicle according to the verification result. It includes a vehicle on-off control device that controls the opening and closing of the vehicle, and a signal output control device that releases jamming operation or blocking when information about the opening and closing of the door of the vehicle is received from the vehicle on-off control device.

Description

Vehicle control method, system and program based on virtual code for authentication {METHOD, SYSTEM AND PROGRAM FOR CONTROLLING VEHICLE BASED ON VIRTUAL CODE FOR AUTHENTICATION}

The present invention relates to a vehicle control method, system, and program based on a virtual code for authentication.

Recently, car sharing services have been spreading at a rapid pace, and the number of car sharing users and target vehicles is also rapidly increasing.

Car sharing is a type of rental car service in which you rent and use the car you want for the required amount of time. The biggest difference from regular car rental is that you reserve a vehicle to use through a service app and use the key key instead of having to deal with the car owner or car sharing service provider. The point is that you can open the car door with your smartphone without a phone.

As such, since the user uses the vehicle without facing the service provider, it is impossible to exchange digital keys. Additionally, in order to control the vehicle doors with a smartphone, a vehicle control device must be installed in the vehicle, and the vehicle digital key controls the vehicle. It is built into the device.

However, if the digital key is placed inside the vehicle like this, there is a problem that the battery of the digital key is easily discharged due to continuous communication between the vehicle and the digital key, and the risk of theft is high.

Additionally, because all processes in the car sharing service are handled through the service app, network communication connecting the service app and the server is very important. In other words, in order for the user to use the service smoothly, communication between the user's smartphone and the server is essential. If the user goes to an area where communication is not available, vehicle control through the service app becomes impossible, preventing the user from using the vehicle. Situations may arise where this is not possible.

Korean Patent No. 10-1316466, 2013.10.01.

The problem to be solved by the present invention is to provide a vehicle control method, system, and program based on a virtual code for authentication.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

A vehicle control system based on a virtual code for authentication according to one aspect of the present invention to solve the above-described problem is an application installed on the terminal of a user using a vehicle rental service, and a control request for the door of the vehicle is received from the application. In this case, a vehicle on-off control device that performs verification of the control request and controls the opening and closing of the door of the vehicle according to the verification result, and information on the opening and closing of the door of the vehicle is received from the vehicle on-off control device. When the connection blocking operation with the outside is canceled, the signal output control device includes a digital key of the vehicle, and when the external connection blocking operation is canceled, the digital key is released. The key controls starting the vehicle.

In the present invention, the operation of blocking the connection with the outside may include an operation of blocking a signal output from the vehicle from being transmitted to the inside of the signal output control device and an operation of blocking power being supplied to the digital key. there is.

In the present invention, the verification is generated by the service server and provided to each of the application and the first control device when communication is possible between the user's terminal and the service server providing the car rental service. It may be performed based on a virtual code for authentication, and if communication between the user's terminal and the service server is impossible, it may be performed based on a virtual code for authentication generated by the application.

In the present invention, the vehicle on-off control device receives from the application a first virtual code for authentication generated by the service server and provided to the application, and the first virtual code for authentication and the generated by the service server. and determine whether there is a match between the second virtual codes for authentication received from the service server, and if it is determined that the first virtual code for authentication matches the second virtual code for authentication, opening and closing the door of the vehicle is permitted. can do.

In the present invention, the vehicle on-off control device receives a virtual code for authentication generated by the application, searches for user identification information based on the virtual code for authentication, and matches the searched user identification information. Stored authority information may be extracted, and opening and closing of the door of the vehicle may be permitted only when the virtual code for authentication is received within a time range corresponding to the extracted authority information.

In the present invention, the vehicle on-off control device is used for authentication only when the generation time when the virtual code for authentication is generated by the application and the reception time when the virtual code for authentication is received from the application are within an error range. A virtual code can be judged as a normal code.

In the present invention, if the verification is successful, the vehicle on/off control device determines the distance between the application and the vehicle based on the strength of the signal according to the control request, and determines the distance between the application and the vehicle if the determined distance is within the set distance. In this case, information about the opening and closing of the door of the vehicle can be transmitted to the signal output control device.

In the present invention, in the external connection blocking operation state for the signal output control device, the first signal sent by the vehicle is blocked, so the first signal is not transmitted to the digital key, and the external connection to the signal output control device is blocked. When the release of the operation is determined, the first signal sent by the vehicle is transmitted to the digital key, and the digital key outputs a second signal in response to the first signal to turn the ignition of the vehicle on or off. You can control it.

In the present invention, the vehicle on/off control device is connected to the OBD terminal inside the vehicle, and when the verification is successful, it can open and close the door of the vehicle by inputting CAN data related to door opening and closing to the OBD terminal.

In the present invention, the application grants authority for the control request to at least one blank card, and the vehicle on/off control device can receive the control request from the at least one blank card through NFC tagging. there is.

A vehicle control system based on a virtual code for authentication according to another aspect of the present invention to solve the above-described problem is an application installed on the terminal of a user using a car rental service and when a request for control of the vehicle is received from the application. , and a signal output control device that verifies the control request and cancels a connection blocking operation with the outside according to the verification result, and the signal output control device includes a digital key of the vehicle therein.

In the present invention, the operation of blocking the connection with the outside may include an operation of blocking a signal output from the vehicle from being transmitted to the inside of the signal output control device and an operation of blocking power being supplied to the digital key. there is.

In the present invention, the verification is performed using a virtual code for authentication generated by the service server and provided to each of the application and the signal output control device when communication is possible between the user's terminal and the service server providing the vehicle rental service. It may be performed based on, and if communication between the user's terminal and the service server is impossible, it may be performed based on the virtual code for authentication generated by the application.

In the present invention, the signal output control device receives a first authentication virtual code generated by the service server and provided to the application from the application,

Determine whether there is a match between the first virtual code for authentication and the second virtual code for authentication generated by the service server and received from the service server, and determine whether the first virtual code for authentication and the second virtual code for authentication are If it is determined that it matches, the operation of blocking the connection with the outside can be canceled.

In the present invention, the signal output control device receives a virtual code for authentication generated by the application, searches for user identification information based on the virtual code for authentication, and matches and stores the searched user identification information. Authorization information may be extracted, and the external connection blocking operation may be canceled only when the virtual code for authentication is received within a time range corresponding to the extracted authorization information.

In the present invention, the signal output control device, the virtual code for authentication only when the generation time when the virtual code for authentication is generated by the application and the reception time when the virtual code for authentication is received from the application are within an error range. The code can be judged as a normal code.

In the present invention, if the verification is successful, the signal output control device determines the distance between the application and the vehicle based on the strength of the signal according to the control request, and if the determined distance is within a preset distance The operation of blocking the connection with the outside can be canceled.

In the present invention, the signal output control device is connected to the OBD terminal inside the vehicle, and when the verification is successful, CAN data related to door opening and closing can be input to the OBD terminal to open and close the door of the vehicle.

In the present invention, the application grants authority for the control request to at least one blank card, and the signal output control device is capable of receiving the control request from the at least one blank card through NFC tagging. there is.

In addition to this, another method for implementing the present invention, another system, and a computer-readable recording medium recording a computer program for executing the method may be further provided.

According to the present invention, when a user requests vehicle control such as opening and closing a door through a service app on a smartphone, regardless of whether there is a communication connection between the smartphone, server, and vehicle, a verification device mounted inside the vehicle authenticates the user for the request. After completing, vehicle control can be performed as requested.

Once user authentication is completed by the verification device, the verification device measures the distance between the user and the vehicle based on the signal strength of the control request, allowing the engine to be started only when the user is located within a certain distance from the vehicle. .

Unlike existing methods, the present invention allows the fob key to be stored inside the vehicle while preserving its shape without disassembling it, and the user can request vehicle control through the smartphone at any time regardless of the network communication status, which is inconvenient. You can use the vehicle without it.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

Figure 1 is a diagram for explaining a vehicle control system based on a virtual code for authentication according to an embodiment of the present invention.
Figure 2 is a flowchart of a vehicle control method based on a virtual code for authentication according to an embodiment of the present invention.
Figure 3 is a diagram illustrating verification when communication is possible between a user's terminal and a service server according to an embodiment of the present invention.
Figure 4 is an exemplary diagram of a search algorithm that searches for user identification information through k-shaped cloud movement for a virtual code for authentication according to an embodiment of the present invention.
Figure 5 is a diagram for explaining verification when communication between a user terminal and a service server is impossible according to an embodiment of the present invention.
Figure 6 is an example diagram illustrating verification of a virtual code for authentication according to an embodiment of the present invention.
Figure 7 is a diagram for explaining a vehicle control system based on a virtual code for authentication according to another embodiment of the present invention.
Figure 8 is a flowchart of a vehicle control method based on a virtual code for authentication according to another embodiment of the virtual code for authentication of the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to provide a general understanding of the technical field to which the present invention pertains. It is provided to fully inform the skilled person of the scope of the present invention, and the present invention is only defined by the scope of the claims.

The terminology used herein is for describing embodiments and is not intended to limit the invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other elements in addition to the mentioned elements. Like reference numerals refer to like elements throughout the specification, and “and/or” includes each and every combination of one or more of the referenced elements. Although “first”, “second”, etc. are used to describe various components, these components are of course not limited by these terms. These terms are merely used to distinguish one component from another. Therefore, it goes without saying that the first component mentioned below may also be a second component within the technical spirit of the present invention.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings commonly understood by those skilled in the art to which the present invention pertains. Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless clearly specifically defined.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

Prior to explanation, the meaning of terms used in this specification will be briefly explained. However, since the explanation of terms is intended to aid understanding of the present specification, it should be noted that if it is not explicitly described as limiting the present invention, it is not used in the sense of limiting the technical idea of the present invention.

In this specification, a 'user' may be a person who uses a vehicle rental service such as car sharing and car rental, but is not limited to this and the user may also be a vehicle owner.

In this specification, the 'user terminal' may be a smartphone used by the user, and the user may install a vehicle control application (hereinafter referred to as application) to remotely control the vehicle he or she has rented during the vehicle rental period.

In this specification, the 'service server' may be a server that provides the car rental service, but is not limited to this and the service server may also be a server that provides a user authentication solution using a virtual code for authentication.

Users can use the car rental service after installing the application on their smartphone and completing registration.

Users can complete user registration by entering the rental period and rental vehicle using an application installed on their smartphone. The application performs the role of registering the user's smartphone to the vehicle or service server. In other words, the application registers by transmitting user identification information to the vehicle or service server.

At this time, the service app can transmit permission information such as the rental period and rental vehicle along with user identification information to the vehicle or service server, so that the permission information is matched to the user identification information and registered.

Once user registration is completed, the vehicle can verify the virtual code for authentication received from the service server or application every time the user uses the vehicle during the rental period. Once user authentication through verification is completed, the user can use the vehicle.

In this specification, 'character' is a component that constitutes a code and includes all or part of uppercase letters, lowercase letters, numbers, and special characters.

In this specification, 'code' refers to a string in which characters are listed.

In this specification, 'virtual code for authentication' refers to a code generated by a virtual code generation means for authentication and a code used to perform user authentication in a virtual code verification means for authentication. In other words, 'virtual code for authentication' refers to a virtual code temporarily assigned to each unit count so that user identification information can be extracted and verified. Here, the virtual code generation means for authentication may be a service server or an application depending on the embodiment. The virtual code verification means for authentication may be a control device (eg, CMS device) mounted inside the vehicle.

In this specification, 'detailed code' refers to a partial code included in the virtual code for authentication.

In this specification, a 'unit count' is a unit defined as being set at a specific time interval and changing as the time interval passes. For example, 1 count can be set and used at a specific time interval (eg, 1.5 seconds).

In this specification, 'virtual code generation function for authentication' refers to a function used to generate a virtual code for authentication.

In this specification, 'cloud movement' means that an object rotates and makes translational movements. In other words, 'rolling movement' means moving while performing both rotational and translational movements, and means that each point of the rotating object moves while touching the moving axis in turn.

In this specification, 'storage location' means a point (count) on the track corresponding to the time when user registration is requested by the user.

In this specification, a 'digital key' is a vehicle key for remotely controlling the operation of the vehicle, and includes, for example, vehicle door opening and closing operations, vehicle ignition on and off operations, etc., and includes smart keys, fob keys, and physical keys. It can contain at least one.

Below, with reference to FIGS. 1 to 6, the specific process of completing user authentication through verification of the virtual code for authentication and using the vehicle will be described in detail.

Figure 1 is a diagram for explaining a vehicle control system based on a virtual code for authentication according to an embodiment of the present invention.

Figure 2 is a flowchart of a vehicle control method based on a virtual code for authentication according to an embodiment of the present invention.

Figure 3 is a diagram illustrating verification when communication is possible between a user's terminal and a service server according to an embodiment of the present invention.

Figure 4 is an example diagram of a search algorithm that searches for user identification information through k-shaped cloud movement for a virtual code for authentication according to an embodiment of the present invention.

Figure 5 is a diagram for explaining verification when communication between a user terminal and a service server is impossible according to an embodiment of the present invention.

Figure 6 is an example diagram illustrating verification of a virtual code for authentication according to an embodiment of the present invention.

As shown in FIG. 1, the vehicle control system includes an application 10, a service server 20, and a vehicle 30.

The application 10 may be a service app that is installed on the terminal of a user using a car rental service (hereinafter referred to as user terminal) and allows the user to control the vehicle during the rental period. Users can receive service apps from external servers such as the App Store and install them on their devices.

Here, the user terminal may be connected to the service server 20 or the vehicle 30 through a network, such as a mobile phone, smartphone, PDA (Personal Digital Assistant), PMP (Portable Multimedia Player), tablet PC, etc., and may be equipped with a camera. It can be any type of handheld-based wireless communication device capable of inputting and outputting various information through the screen. All operations of the application 10 related to the vehicle control method based on the virtual code for authentication of the present invention, which will be described below, can be performed in the same way on the user terminal on which the application 10 is installed.

The service server 20 may be a server that provides a vehicle rental service or a server that provides a user authentication solution using a virtual code for authentication. Depending on the embodiment, the service server 20 may collect various vehicle data generated while a user using a vehicle rental service drives the vehicle during the vehicle rental period.

The vehicle 30 is a vehicle that a user rents for a specific period (rental period). During the rental period, the vehicle 30 can be controlled according to various control request signals received from the application 10 installed on the user terminal.

The vehicle 30 may include a vehicle on/off control device 32, a signal output control device 34, and an OBD terminal 36.

The vehicle on-off control device 32 may be a device mounted inside the vehicle 30 and connected to the OBD terminal 36 inside the vehicle 30.

The vehicle on-off control device 32 may transmit various vehicle data generated while the user who rents the vehicle uses the vehicle to the service server 20. Through this, the service server 20 can check how the user is using or has used the vehicle 30.

The vehicle on-off control device 32 can control the vehicle according to various control requests received from the application 10. Specifically, the vehicle on/off control device 32 can control operations including opening and closing doors, opening and closing trunks, opening and closing windows, turning emergency lights on and off, and turning lights on and off.

The signal output control device 34 is a device installed inside the vehicle 30 and connected to the vehicle on-off control device 32 by wire or wirelessly. The signal output control device 34 maintains the shape of the FOB key inside. It can be stored intact (i.e. without decommissioning the FOB key).

The signal output control device 34 receives a control request from an application installed on a specific user terminal and allows the digital key located in the signal output control device 34 to control the ignition of the vehicle 30 on and off only when user authentication is completed. can do.

Depending on the embodiment, the signal output control device 34 maintains the external connection blocking operation state as a default so that the digital key (FOB key) stored inside receives the first signal (for example, LF signal) sent from the vehicle 30. ) can be prevented from receiving. Afterwards, when user authentication is completed, the external connection blocking operation of the signal output control device 34 is released, and the digital key (FOB key) receives the first signal (e.g., LF signal) sent from the vehicle 30 and , and in response to this, a second signal (for example, an RF signal) is transmitted. The ignition of the vehicle may be controlled to be on or off according to the second signal of the digital key (FOB key).

Here, depending on the embodiment, the operation of blocking the connection with the outside may be an operation of blocking the signal output by the vehicle from being transmitted inside the signal output control device (jamming operation).

Depending on the embodiment, the operation of blocking the connection with the outside may include an operation of blocking power being supplied to the digital key. Specifically, the signal output control device 34 is connected to a battery (eg, a dry cell) of a digital key (FOB key) and can serve as a switch that controls on and off the power of the battery supplied to the digital key. The signal output control device 34 keeps the battery power off (so that current does not flow) by default, and turns the battery power on (so that current flows) only when user authentication is completed, and activates the digital key (so that current does not flow). FOB key) can be used to control starting the vehicle.

When user authentication is completed, current flows to the electrode and the digital key is turned on accordingly, allowing the digital key to receive the first signal (eg, LF signal) sent from the vehicle 30. And the digital key transmits a second signal (for example, an RF signal) in response to the first signal, and the ignition of the vehicle can be controlled to be on or off according to the second signal of the digital key (FOB key). do.

In this way, allowing the digital key to operate selectively through a jamming operation of the signal output control device 34 or a power cut of the digital key means that, if there is no jamming operation or a power cut, the digital key stored inside the vehicle 30 The key continues to output a second signal in response to the first signal sent from the vehicle 30 (even when there is no control request from the user), and as a result, the battery of the digital key is quickly consumed, causing a problem. This is to prevent such problematic situations from occurring.

The OBD terminal 36 is connected to the vehicle on-off control device 32 and performs operations including vehicle opening and closing, trunk opening and closing, window opening and closing, emergency light on and off, and light on and off from the vehicle on and off control device 32. By receiving CAN DATA, the doors, windows, trunk, etc. of the vehicle 30 can be opened or closed, and emergency lights, lights, etc. can be turned on or off.

Here, the application 10, service server 20, and vehicle 30 can transmit and receive various information through a communication network (not shown). Specifically, data transmission and reception between the application 10 (more specifically, a user terminal on which the application 10 is installed) and the service server 20 and the service server 20 and the vehicle 30 (more specifically, vehicle on-off control) Data transmission and reception between the device 32) and data transmission and reception between the application 10 (more specifically, the user terminal on which the application 10 is installed) and the vehicle 30 (more specifically, the vehicle on-off control device 32). Can be performed through the communication network (not shown).

At this time, various types of communication networks (not shown) may be used, such as WLAN (Wireless LAN), Wi-Fi, Wibro, Wimax, and HSDPA (High Speed Downlink Packet Access). ) or wired communication methods such as Ethernet, xDSL (ADSL, VDSL), HFC (Hybrid Fiber Coax), FTTC (Fiber to The Curb), and FTTH (Fiber To The Home) can be used. there is.

Meanwhile, the communication network (not shown) is not limited to the communication methods presented above, and may include all types of communication methods that are widely known or will be developed in the future in addition to the communication methods described above.

In addition, data transmission and reception between the application 10 (more specifically, the user terminal on which the application 10 is installed) and the vehicle 30 (more specifically, the vehicle on-off control device 32) is performed through short-range wireless communication (e.g. , Bluetooth).

Additionally, the vehicle on/off control device 32 and the signal output control device 34 may be connected through short-range wireless communication (eg, Bluetooth) to transmit and receive data.

When a user rents a vehicle, the user may be registered with the service server 20 and the vehicle 30.

Depending on the embodiment, the application 10 may transmit user identification information to the service server 20 and the vehicle 30. Here, the user identification information may be, but is not limited to, a membership code given to the user when signing up for the application 10. Thereafter, the application 10 may transmit authority information to the service server 20 and the vehicle 30. The service server 20 and the vehicle 30 can complete user registration by matching and storing authority information in the area where user identification information is stored.

When a user signs up for the application 10, the application 10 and the service server 20 can store a virtual code generation function for authentication for the user and start running it. Then, when the user requests to rent a specific vehicle 30, a search algorithm corresponding to the virtual code generation function for authentication for the specific user is provided to the specific vehicle 30 to identify the user to the specific vehicle 30. Registration can be performed.

Depending on the embodiment, the application 10 may transmit user identification information to the service server 20. Here, the user identification information may be, but is not limited to, a membership code given to the user when signing up for the application 10. Afterwards, the application 10 can transmit authorization information to the service server 20. The service server 20 can complete registration for the user by matching the authority information to the area where the user identification information is stored. Additionally, the service server 20 transmits user registration-related data to the vehicle 30 and allows the vehicle 30 to store the data, thereby allowing the user to be registered in the vehicle 30 as well.

Once the user's vehicle rental contract is completed through these processes, the user can use the vehicle 30. Hereinafter, the process performed when the user uses the vehicle 30 during the rental period will be described in detail.

Referring to FIG. 2, the user may request control of the door of the vehicle 30 through the application 10 installed on the user terminal (S110).

Then, when a control request for the door of the vehicle is received from the application 10, the vehicle on/off control device 32 performs verification of the control request (S120), and according to the verification result, the vehicle door The opening and closing can be controlled (S130).

At this time, the verification is performed in different ways when communication is possible between the user terminal on which the application 10 is installed and the service server 20 and when communication is not possible between the user terminal and the service server 20. .

Depending on the embodiment, when communication is possible between the application 10 and the service server 20, it is generated by the service server 20 and sent to each of the application 10 and the vehicle on-off control device 32. Verification can be performed based on the provided virtual code for authentication.

The user may make a vehicle control request, for example, by selecting “door open”, through the application 10 while staying at a certain distance or more from the vehicle 30. At this time, this specification describes a series of processes performed when the vehicle control request is “door open,” but “door closed,” “window open/closed,” “trunk open/closed,” and “hazard light on.” The same process as “door open” can be performed for all vehicle control requests such as “/off” and “light on/off.”

Referring to FIG. 3, in response to a control request from the application 10, the service server 20 may generate a virtual code for authentication and provide it to the application 10 and the vehicle on-off control device 32, respectively ( S1111 and S1112). At this time, the virtual code for authentication transmitted to the application 10 is called a first virtual code for authentication, and the virtual code for authentication transmitted to the vehicle on-off control device 32 is called a second virtual code for authentication.

In this case, the service server 20 may serve as a means for generating a virtual code for authentication.

The service server 20 is responsible for generating one or more detailed codes based on user identification information.

The virtual code generation function for authentication includes one or more detailed code generation functions. For example, if the virtual code for authentication includes multiple detailed codes, the virtual code generation function for authentication generates multiple detailed codes using multiple detailed code generation functions, and a detailed code that combines multiple detailed codes The first virtual code for authentication is generated using the code combining function.

At this time, the virtual code for authentication is generated for each unit count by a virtual code generating means for authentication, that is, a dedicated program installed on the service server 20, and may mean one time password (OTP).

In one embodiment, the service server 20 may use user identification information as one of the seed data of the virtual code generation function for authentication. As a specific example, the service server 20 uses one detailed code generation function to generate each detailed code using user identification information as seed data for each detailed code generating function. At this time, the service server 20 may generate each detailed code using the time point or count value when vehicle control is requested from the application 10.

In one embodiment, the service server 20 may generate a first code and a second code by including a first function and a second function as a detailed code generation function. At this time, in order to increase security, the service server 20 only includes a first function for generating the first code and a second function for generating the second code as a detailed code generation function, and the Data on correlation may not be included.

The service server 20 performs the role of combining one or more detailed codes using a virtual code generation function for authentication and generating a virtual code for authentication. In one embodiment, a virtual code for authentication is generated by combining a plurality of detailed codes according to specific rules. The virtual code generation function for authentication includes rules for combining multiple detailed codes (i.e., detailed code combination function). That is, the service server 20 can combine one or more detailed codes using the detailed code combining function included in the virtual code generation function for authentication.

Various methods can be applied to generate one virtual code for authentication by combining multiple detailed codes. As an example of a detailed code combination function, the service server 2 may generate a first virtual code for authentication by alternately arranging an N-digit first code and an N-digit second code. Additionally, as another example, the detailed code combining function may be a function that combines a second code after a first code. As the number of detailed codes included in the virtual code for authentication increases, various detailed code combination functions can be created.

In addition, in one embodiment, when the virtual code for authentication is generated as a combination of the first code and the second code according to a specific rule, the first code and the second code are used to search the storage location of the user identification information within the search algorithm. can perform each role. For example, the first code sets the starting point of the storage location search, and the second code searches from the starting point to the storage location of the user identification information (i.e., the area where the user identification information is stored) according to a specific search method. Set the path. Thereafter, when the first authentication virtual code generated normally for each unit count is provided from the service server 20, the vehicle on-off control device 32 starts a search path corresponding to the second code from the starting point corresponding to the first code. Accordingly, the moved point is judged to be an area where user identification information is stored. A specific method of searching for the storage location of user identification information based on the first code and second code constituting the virtual code for authentication will be described later.

As an example of a method in which the service server 20 generates a detailed code, the service server 20 generates a new detailed code for each unit count, and accordingly, the service server 20 generates a new virtual code for authentication for each unit count. creates . Virtual codes for authentication that are newly generated for each unit count are not duplicated. Specifically, the service server 20 ensures that the virtual code for authentication, which is newly generated for each unit count, is not duplicated during the rental period determined according to the rental contract of a specific user, and is also not duplicated among users using the car rental service. can be set.

As a specific example of preventing duplicate generation of virtual codes for authentication, when generating an N-digit first code or second code with M characters, the detailed code generation function included in the virtual code generation function for authentication is MN. Codes can be generated as the first code or the second code, and each code is matched for each count from the initial point when the detailed code generation function is driven. For example, when the unit count is set to 1 second, MN different codes are matched every second from the time the detailed code generation function is first run. And, if the cycle of using a specific detailed code generation function is set to a time length shorter than the time length corresponding to the MN count (for example, if 1 count is 1 second, MN seconds), the first code or the second code is a usage cycle. During this process, the same code is not duplicated. That is, when the count increases over time and the user makes a vehicle control request to the service server 20 at a specific point in time, the service server 20 provides a code value matching the count corresponding to the specific point in time. It can be generated as 1 code or 2 code.

Specifically, if capital letters and numbers from 0 to 9 are used as characters that can be included in the code (i.e., 36 characters are used) and 6 digits are assigned to the first code and the second code, the service server ( 20) can provide 366 codes as the first code and the second code. At this time, the service server 20 may match each code to each count and provide the first and second codes changed for each count.

As another specific embodiment of preventing duplicate generation of virtual codes for authentication, when the usage cycle of the function for a specific user has elapsed, a function that generates the first code or the second code (i.e., the first function or the second function ) or change the matching relationship between the first code and the second code so that a virtual code for authentication that is different from the previous usage cycle is generated. When the virtual code for authentication combines the first code generated by the first function and the second code generated by the second function, when the first code generation function or the second code generation function is changed, the service server (20 ) can apply the virtual code for authentication function, which generates a first virtual code for authentication that is different from the previous cycle, to a new usage cycle as the order in which the first code or the second code appears is different from the previous usage cycle. In addition, the service server 20 prevents the same code as the first virtual code for authentication used in the previous usage cycle from appearing as the first virtual code for authentication for each count in the new usage cycle (i.e., generates according to the first function The first function and the second function can be selected so that the matching relationship between the first code and the second code generated according to the second function is not included among the matching relationships included in the previous use cycle in all counts of the new use cycle. . In other words, after the usage cycle in which MN codes can be applied once has passed, the virtual code for authentication in a new usage cycle in which no virtual code for authentication overlapping with the previous usage cycle is generated through adjustment or renewal of the virtual code generation function for authentication. A creation function can be applied.

Additionally, in another embodiment, the virtual code generation function (or detailed code generation function) for authentication applies any one of a plurality of listing rules that lists M characters in ascending order. That is, the service server 20 can apply various rules for listing M characters in ascending order to the detailed code generation function included in the virtual code generation function for authentication. For example, the listing rule for listing capital letters of the alphabet in ascending order is the general order: A, B, C,... , Z can be in order, A, C, B,… , may be in Z order. As the listing rules change in the virtual code generation function for authentication, the order in which codes are matched to each count changes from the initial point when the virtual code generation function for authentication is run.

In the above, it has been explained that the service server 20 generates a virtual code for authentication, but more specifically, the virtual code for authentication will be generated using a dedicated program for generating a virtual code for authentication included in the service server 20. You can.

Referring again to FIG. 3, the application 10 may transmit the first virtual code for authentication received from the service server 20 to the vehicle on-off control device 32 (S1113).

The vehicle on/off control device 32 may perform verification using the first virtual code for authentication received from the application 10 and the second virtual code for authentication received from the service server 20. At this time, depending on the embodiment, when receiving the second authentication virtual code from the service server 20, the vehicle on-off control device 32 provides control information corresponding to the vehicle control request by the user terminal 20. You can receive it together. Or, depending on the embodiment, when the vehicle on/off control device 32 receives the first virtual code for authentication from the user terminal 10, the control information corresponding to the vehicle control request by the user terminal 20 is included. You can also receive it. Alternatively, depending on the embodiment, the virtual code for authentication generated by the service server 20 may be generated using not only user identification information but also control information.

In other words, the vehicle on-off control device 32 can serve as a virtual code verification means for authentication. The vehicle on-off control device 32 determines whether the first virtual code for authentication matches the second virtual code for authentication, and determines that the first virtual code for authentication and the second virtual code for authentication match. If determined, opening and closing of the door of the vehicle may be permitted.

Specifically, the vehicle on/off control device 32 extracts user identification information from each of the first virtual code for authentication and the second virtual code for authentication, and performs user authentication through whether or not the extracted user identification information matches. It can be done.

In one embodiment, the vehicle on-off control device 32 receives a request for user authentication by receiving a first virtual code for authentication and a second virtual code for authentication generated by a dedicated program (the service server includes a dedicated program). .

The vehicle on-off control device 32 performs the role of extracting one or more detailed codes included in the first virtual code for authentication and the second virtual code for authentication.

In one embodiment, the vehicle on-off control device 32 includes a detailed code combining function included in the virtual code generation function for authentication. Therefore, when the first virtual code for authentication and the second virtual code for authentication each include a plurality of detailed codes, the vehicle on-off control device 32 applies the detailed code combining function to combine the first virtual code for authentication and the second virtual code. 2 Multiple detailed codes can be extracted from each virtual code for authentication. For example, when the service server 20 generates a virtual code for authentication by combining two detailed codes (i.e., a first code and a second code), the vehicle on-off control device 32 uses the first authentication code. The first code and the second code can be separated from each character array of the virtual code and the second virtual code for authentication by applying a detailed code combining function.

The vehicle on/off control device 32 performs a role of searching for user identification information within a search algorithm based on one or more extracted detailed codes. Here, the search algorithm matches the virtual code generation function for authentication used when generating the virtual code for authentication in the service server 20. Various methods can be applied to search for the storage location of user identification information in the vehicle on-off control device 32 based on each detailed code. In order for the vehicle on/off control device 32 to search for a storage location based on a plurality of detailed codes, a correlation may be included between the detailed codes.

Here, the storage location refers to the point (count) on the track corresponding to the time when registration was requested by the user. That is, when a track for that user is driven within the vehicle on/off control device 32, and registration is requested by a specific user at a specific time, the count corresponding to that time (i.e., the time of registration from the last driving of the track) The user identification information is stored and registered in the elapsed count. And, the user's authority information is matched and stored in the area where the user identification information is stored.

In more detail, when the user completes signing up for the application 10, the track for that user begins to run, and when the user requests registration to rent a vehicle after a certain period of time has elapsed after signing up, the track is requested at the time of the registration request. User identification information is stored at the corresponding point and registration is completed. After the vehicle band contract ends, if the user wishes to rent a second vehicle, registration can be completed by storing the user identification information at the point corresponding to the second registration request on the same track for the user terminal 10. You can.

When the virtual code for authentication consists of a first code and a second code, in an embodiment where there is a correlation between the detailed codes, the vehicle on-off control device 32 determines a search start point corresponding to the first code, , the point moved from the search start point along the search path corresponding to the second code can be found as the storage location of the user identification information. That is, the detailed code may include a first code that sets the start point of the search and a second code that sets the search path from the search start point to the storage location of the user identification information according to a specific search method. there is.

In addition, in another embodiment, as the service server 20 provides a new virtual code for authentication for each unit count, the vehicle on-off control device 32 is based on the first code and the second code that change for each count. You can search for the storage location of user identification information by setting the search start point and search path.

Additionally, in another embodiment, the vehicle on/off control device 32 may include a search algorithm to find the storage location of user identification information using a plurality of correlated detailed codes. The search algorithm is an algorithm that enables searching the storage location (area where user identification information is stored) when applying each detailed code included in the virtual code for authentication, and is used when generating the virtual code for authentication in the service server 20. It matches the virtual code generation function for authentication.

For example, if the virtual code for authentication includes a first code that determines the search start point of the storage location and a second code that suggests the direction of the storage location from the search start point, the search algorithm corresponds to the first code. This is an algorithm that adjusts so that when a direction corresponding to a second code is indicated at a point, a storage location that matches the user's registration time is placed at that location.

By using a search algorithm, the vehicle on-off control device 32 can search for the storage location of user identification information even if the first code and the second code included in the virtual code for authentication are changed. The search algorithm can be applied in various ways, and specific examples will be described later. However, the search algorithm is not limited to the examples described later.

For example, referring to Figure 4, the search algorithm is a k-square (k is MN) that moves along a track where MN codes corresponding to the first code are listed, and the vertex of the k-square is on the first code track. When the code moves corresponding to the point where it is placed, each vertex of the k-square matches the storage location of the user identification information, and the point where the first code track (i.e., the first track) and the k-square correspond to the first code It can be a starting point for searching for a storage location corresponding to . At this time, the vehicle on-off control device 32 may apply rolling movement of the k-square so that the vertex of the k-square touches the point corresponding to the extracted first code. Through this, the vehicle on-off control device 32 sets an angle corresponding to the second code at a position on the first track where the k-square is in contact (for example, a specific angle divided by 180 degrees into MN points toward the vertex of the k-square). ), the vertex of the k-square, which is the storage location where the user identification information corresponding to the virtual code for authentication is stored, can be searched.

Specifically, as shown in FIG. 4, the vehicle on-off control device 32 moves the k-square to a point corresponding to the first code (that is, while making each vertex of the k-square contact each point on the track in turn) move). Afterwards, the vehicle on/off control device 32 searches for a vertex corresponding to the storage location of the user identification information by indicating the angular direction corresponding to the second code.

When user identification information is searched by the vehicle on/off control device 32 using the first code and the second code of the first virtual code for authentication and the second virtual code for authentication within the search algorithm, respectively, the two searched Determine whether the user identification information matches. If the two user identification information matches, it is determined that user authentication has been completed, and operations for controlling the door opening and closing can be performed.

Specifically, if the verification is successful, the vehicle on/off control device 32 inputs CAN data related to door opening and closing corresponding to the received control information to the OBD terminal 36 inside the vehicle 30 to control the vehicle 30. The door can be opened and closed.

Depending on the embodiment, when communication between the application 10 and the service server 20 is impossible, based on the virtual code for authentication generated by the application 10 and provided to the vehicle on-off control device 32, Verification may be performed.

The user may request vehicle control, for example, by selecting “door open,” through the application 10 installed on the user terminal while being at a certain distance or more from the vehicle 30. At this time, this specification describes a series of processes performed when the vehicle control request is “door open,” but “door closed,” “window open/closed,” “trunk open/closed,” and “hazard light on.” The same process as “door open” can be performed for all vehicle control requests such as “/off” and “light on/off.”

Referring to FIG. 5, when the application 10 determines that communication between the user terminal and the service server 20 is impossible, it transmits a door control request signal including control information to the vehicle on/off control device 32. At this time, the application 10 may generate a virtual code for authentication (S1121) and transmit the generated virtual code for authentication to the vehicle on-off control device 32 (S1122). The vehicle on/off control device 32 may receive the virtual code for authentication (S1123). Depending on the embodiment, the vehicle on/off control device 32 may receive the control request signal and the virtual code for authentication sequentially, or may also receive the control request signal and the virtual code for authentication together.

In this case, the application 10 may serve as a means of generating a virtual code for authentication.

The application 10 is responsible for generating one or more detailed codes based on user identification information.

The virtual code generation function for authentication includes one or more detailed code generation functions. For example, if the virtual code for authentication includes multiple detailed codes, the virtual code generation function for authentication generates multiple detailed codes using multiple detailed code generation functions, and a detailed code that combines multiple detailed codes Create a virtual code for authentication using the code combination function.

At this time, the virtual code for authentication is generated for each unit count by a virtual code generating means for authentication, that is, a dedicated program included in the application 10, and may mean one time password (OTP).

In one embodiment, the application 10 may use user identification information as one of the seed data of the virtual code generation function for authentication. As a specific example, the application 10 uses one detailed code generation function to generate each detailed code using user identification information as seed data for each detailed code generation function. At this time, the application 10 can generate each detailed code using the time or count value when the user requests vehicle control.

In one embodiment, the application 10 may generate a first code and a second code by including a first function and a second function as a detailed code generation function. At this time, in order to increase security, the application 10 only includes a first function for generating the first code and a second function for generating the second code as a detailed code generation function, and the correlation between the first code and the second code is Data about relationships may not be included.

The application 10 performs the function of combining one or more detailed codes using a virtual code generation function for authentication and generating a virtual code for authentication. In one embodiment, a virtual code for authentication is generated by combining a plurality of detailed codes according to specific rules. The virtual code generation function for authentication includes rules for combining multiple detailed codes (i.e., detailed code combination function). That is, the application 10 can combine one or more detailed codes using the detailed code combining function included in the virtual code generation function for authentication.

Various methods can be applied to generate one virtual code for authentication by combining multiple detailed codes. As an example of a detailed code combination function, the application 10 can generate a virtual code for authentication by alternately arranging an N-digit first code and an N-digit second code. Additionally, as another example, the detailed code combining function may be a function that combines a second code after a first code. As the number of detailed codes included in the virtual code for authentication increases, a variety of detailed code combination functions can be created.

In addition, in one embodiment, when the virtual code for authentication is generated as a combination of the first code and the second code according to a specific rule, the first code and the second code are used to search the storage location of the user identification information within the search algorithm. can perform each role. For example, the first code sets the starting point of the storage location search, and the second code searches from the starting point to the storage location of the user identification information (i.e., the area where the user identification information is stored) according to a specific search method. Set the path. Thereafter, when the application 10 provides a virtual code for authentication that is normally generated for each unit count, the vehicle on-off control device 32 moves from the starting point corresponding to the first code along the search path corresponding to the second code. A point is determined to be an area where user identification information is stored. A specific method of searching for the storage location of user identification information based on the first code and second code constituting the second virtual code for authentication will be described later.

As an example of how the application 10 generates a detailed code, the application 10 generates a new detailed code for each unit count, and accordingly, the application 10 generates a new virtual code for authentication for each unit count. . Virtual codes for authentication that are newly generated for each unit count are not duplicated. Specifically, the application 10 is set so that the virtual code for authentication, which is newly generated for each unit count, is not duplicated during the rental period determined according to the rental contract of a specific user, and is also not duplicated among users using the car rental service. It can be.

As a specific example of preventing duplicate generation of virtual codes for authentication, when generating an N-digit first code or second code with M characters, the detailed code generation function included in the virtual code generation function for authentication is MN. Codes can be generated as the first code or the second code, and each code is matched for each count from the initial point when the detailed code generation function is driven. For example, when the unit count is set to 1 second, MN different codes are matched every second from the time the detailed code generation function is first run. And, if the cycle of using a specific detailed code generation function is set to a time length shorter than the time length corresponding to the MN count (for example, if 1 count is 1 second, MN seconds), the first code or the second code is a usage cycle. During this process, the same code is not duplicated. That is, when the count increases over time and the user requests vehicle control through the application 10 at a specific point in time, the application 10 sends a code value matching the count corresponding to the specific point in time to the first It can be generated with a code or a second code.

Specifically, if capital letters and numbers from 0 to 9 are used as characters that can be included in the code (i.e., 36 characters are used), and 6 digits are assigned to the first code and the second code, the application (10 ) can provide 366 codes as the first code and the second code. At this time, the application 10 may match each code to each count and provide a first code and a second code that are changed for each count.

As another specific embodiment of preventing duplicate generation of virtual codes for authentication, when the usage cycle of the function for a specific user has elapsed, a function that generates the first code or the second code (i.e., the first function or the second function ) or change the matching relationship between the first code and the second code so that a virtual code for authentication that is different from the previous usage cycle is generated. When the virtual code for authentication combines the first code generated by the first function and the second code generated by the second function, when the first code generation function or the second code generation function is changed, the application 10 As the order in which the first code or the second code appears is different from the previous usage cycle, the virtual code for authentication function that generates a virtual code for authentication that is different from the previous cycle can be applied to the new usage cycle. In addition, the application 10 prevents the same code as the virtual code for authentication used in the previous usage cycle from appearing as the virtual code for authentication for each count in the new usage cycle (that is, the first code generated according to the first function and The first function and the second function may be selected so that the matching relationship of the second code generated according to the second function is not included among the matching relationships included in the previous use cycle in all counts of the new use cycle. In other words, after the usage cycle in which MN codes can be applied once has passed, the virtual code for authentication in a new usage cycle in which no virtual code for authentication overlapping with the previous usage cycle is generated through adjustment or renewal of the virtual code generation function for authentication. A creation function can be applied.

Additionally, in another embodiment, the virtual code generation function (or detailed code generation function) for authentication applies any one of a plurality of listing rules that lists M characters in ascending order. That is, the application 10 can apply various rules for listing M characters in ascending order to the detailed code generation function included in the virtual code generation function for authentication. For example, the listing rule for listing capital letters of the alphabet in ascending order is the general order: A, B, C,... , Z can be in order, A, C, B,… , could also be in Z order. As the listing rules change in the virtual code generation function for authentication, the order in which codes are matched to each count changes from the initial point when the virtual code generation function for authentication is run.

In the above, it was explained that the application 10 generates a virtual code for authentication, but more specifically, the virtual code for authentication can be generated using a dedicated program for generating a virtual code for authentication included in the application 10. .

Referring again to FIG. 5, the vehicle on/off control device 32 may perform verification using the virtual code for authentication received from the application 10.

In other words, the vehicle on-off control device 32 can serve as a virtual code verification means for authentication. The vehicle on/off control device 32 searches for user identification information based on the received virtual code for authentication, extracts stored authority information that matches the searched user identification information, and generates authority information corresponding to the extracted authority information. Opening and closing of the door of the vehicle can be permitted only when the virtual code for authentication is received within the time range.

That is, the vehicle on/off control device 32 allows opening and closing of the vehicle door only when a vehicle control request is made during the user's rental period. In other words, even if the verification of the virtual code for authentication has been completed (i.e., even if the request was received from a registered user), vehicle control may not be performed if the request is not made within the rental period. Since this is a case where communication with the service server 20 is not possible, the vehicle 30 directly determines whether the request has been received within the time range allowed for a specific user. If communication is made with the service server 20, if the time of the control request from the user is not included in the rental period, the service server 20 may determine this and not generate the virtual code for authentication itself. Additionally, if the control request is not received within the allowed time range, the vehicle 30 or the service server 20 may provide a notification informing the user terminal that the contract period has ended.

Specifically, the vehicle on/off control device 32 extracts user identification information from the virtual code for authentication, determines whether the extracted user identification information matches the user information registered in the vehicle 30, and determines whether the virtual code for authentication is User authentication can be performed by determining whether the code reception point is within a time range corresponding to the extracted user identification information and the matched authorization information.

In one embodiment, the vehicle on/off control device 32 receives a virtual code for authentication generated by a dedicated program (the dedicated program is included in the application 10) and is requested for user authentication.

The vehicle on-off control device 32 each performs the role of extracting one or more detailed codes included in the virtual code for authentication.

In one embodiment, the detailed code extraction unit (not shown) includes a detailed code combining function included in the virtual code generation function for authentication. Therefore, when the virtual code for authentication includes a plurality of detailed codes, the vehicle on-off control device 32 can extract a plurality of detailed codes from the virtual code for authentication by applying a detailed code combining function. For example, when the user terminal 10 generates a virtual code for authentication by combining two detailed codes (i.e., a first code and a second code), the vehicle on-off control device 32 generates a virtual code for authentication. The first code and the second code can be separated from the character array by applying a detailed code combining function.

The vehicle on/off control device 32 performs a role of searching for user identification information within a search algorithm based on one or more extracted detailed codes. Here, the search algorithm matches the virtual code generation function for authentication used when generating the virtual code for authentication in the application 10. Various methods can be applied to search for the storage location of user identification information based on each detailed code in the storage location search unit (not shown). In order for the storage location search unit (not shown) to search the storage location based on a plurality of detailed codes, a correlation may be included between the detailed codes.

Here, the storage location refers to the point (count) on the track corresponding to the time when user registration was requested by the user. That is, when a track for that user is driven within the vehicle on/off control device 32, and registration is requested by a specific user at a specific time, the count corresponding to that time (i.e., the time of registration from the last driving of the track) The user identification information is stored and registered in the elapsed count. And, the user's authority information is matched and stored in the area where the user identification information is stored.

In more detail, when the user completes signing up for the application 10, the track for that user begins to run, and when the user requests registration to rent a vehicle after a certain period of time has elapsed after signing up, the track is requested at the time of the registration request. User identification information is stored at the corresponding point and registration is completed. After the contract ends, if the user wishes to rent a vehicle a second time, registration can be completed by storing the user identification information at the point corresponding to the second registration request on the same track for the user.

When the virtual code for authentication consists of a first code and a second code, in an embodiment where there is a correlation between the detailed codes, the vehicle on-off control device 32 determines a search start point corresponding to the first code, , the point moved from the search start point along the search path corresponding to the second code can be found as the storage location of the user identification information. That is, the detailed code may include a first code that sets the start point of the search and a second code that sets the search path from the search start point to the storage location of the user identification information according to a specific search method. there is.

In addition, in another embodiment, as the application 10 provides a new virtual code for authentication for each unit count, the vehicle on-off control device 32 uses the first code and the second code that change for each count. You can search for the storage location of user identification information by setting the search start point and search path.

Additionally, in another embodiment, the vehicle on/off control device 32 may include a search algorithm to find the storage location of user identification information using a plurality of correlated detailed codes. The search algorithm is an algorithm that enables searching the storage location (area where user identification information is stored) when applying each detailed code included in the virtual code for authentication, which was used when generating the virtual code for authentication in the application 10. It matches the virtual code generation function for authentication.

For example, if the virtual code for authentication includes a first code that determines the search start point of the storage location and a second code that suggests the direction of the storage location from the search start point, the search algorithm corresponds to the first code. This is an algorithm that adjusts so that when a direction corresponding to a second code is indicated at a point, a storage location that matches the user's registration time is placed at that location.

By using a search algorithm, the vehicle on-off control device 32 can search for the storage location of user identification information even if the first code and the second code included in the virtual code for authentication are changed. The search algorithm can be applied in various ways, and specific examples will be described later. However, the search algorithm is not limited to the examples described later.

For example, referring to Figure 4, the search algorithm is a k-square (k is MN) that moves along a track where MN codes corresponding to the first code are listed, and the vertex of the k-square is on the first code track. When the code moves corresponding to the point where it is placed, each vertex of the k-square matches the storage location of the user identification information, and the point where the first code track (i.e., the first track) and the k-square correspond to the first code It can be a starting point for searching for a storage location corresponding to . At this time, the storage location search unit (not shown) may apply rolling movement to the k-square so that the vertex of the k-square touches the point corresponding to the first code extracted from the detailed code extraction unit (not shown). Through this, the storage location search unit (not shown) determines the angle corresponding to the second code at the position on the first track where the k-square is in contact (for example, a specific angle divided by 180 degrees into MN points toward the vertex of the k-square). ), the vertex of the k-square, which is the storage location where the user identification information corresponding to the first virtual code for authentication is stored, can be searched.

Specifically, as shown in FIG. 4, the vehicle on-off control device 32 moves the k-square to a point corresponding to the first code (that is, while making each vertex of the k-square contact each point on the track in turn) move). Afterwards, the vehicle on/off control device 32 searches for a vertex corresponding to the storage location of the user identification information by indicating the angular direction corresponding to the second code.

When user identification information is searched by the vehicle on/off control device 32 using the first code and the second code of the virtual code for authentication within the search algorithm, the searched user identification information is registered in the vehicle 30. Determine whether it is identical to the identification information. Then, it is determined whether the time of receipt of the virtual code for authentication is within the rental period through the authority information matched to the searched user identification information. If the user identification information is the same and the reception time is within the rental period, it is determined that user authentication has been completed and an operation for controlling the door opening and closing can be performed.

If the verification is successful, the vehicle on/off control device 32 inputs CAN data related to door opening and closing corresponding to the received control information to the OBD terminal 36 inside the vehicle 32 to open and close the door of the vehicle. It can be done as much as possible.

According to the embodiment, the vehicle on-off control device 32 determines the time when the virtual code for authentication is received from the application 10 (reception time) and the virtual code for authentication is generated by the virtual code for authentication function in the application 10. It can also serve to verify the virtual code for authentication by comparing the time it was created (time of creation).

Referring to FIG. 6, the vehicle on/off control device 32 has a generation time of the virtual code for authentication generated by the application 10 and a reception time of the virtual code for authentication received from the application 10. Only if it is within the error range, the virtual code for authentication can be judged to be a normal code.

Referring again to FIG. 2, the signal output control device 34 determines whether to release the connection blocking operation with the outside according to the verification result, and according to the determination result, the vehicle located inside the signal output control device 34 The digital key of (30) can control the starting of the vehicle (30) (S140).

Specifically, after the verification is successful, if information about the opening and closing of the door of the vehicle is received from the vehicle on-off control device 32, the signal output control device 34 can cancel the operation of blocking the connection with the outside. there is. Accordingly, the digital key can control the vehicle ignition on or off. Here, the operation of blocking the connection with the outside may include an operation of blocking a signal output from the vehicle from being transmitted to the inside of the signal output control device and an operation of blocking power from being supplied to the digital key.

Depending on the embodiment, after the verification is successful, the vehicle on/off control device 32 determines the distance between the application 10 and the vehicle 30 based on the strength of the signal according to the control request, and If the determined distance is within a preset distance, information about the opening and closing of the door of the vehicle can be transmitted to the signal output control device 34. Accordingly, the signal output control device 34 can cancel the operation of blocking connection with the outside.

At this time, as described above, the jamming operation interrupts communication between the digital key and the vehicle 30 to prevent the digital key from outputting a second signal in response to the first signal sent by the vehicle 30, Blocking prevents current from flowing to the digital key and keeps the power of the digital key in an off state.

Accordingly, in a jamming operation or battery power-off state of the signal output control device 34, the first signal (e.g., LF signal) sent by the vehicle 30 is blocked and is not transmitted to the digital key of the vehicle 30. The first signal is not transmitted. Thereafter, when information on door opening/closing is received from the vehicle on/off control device 32 and the jamming operation or blocking of the signal output control device 34 is released, the first signal sent by the vehicle 30 is transmitted to the vehicle. It is transmitted to the digital key of (30), and the digital key of the vehicle (30) outputs a second signal (e.g., RF signal) in response to the first signal to turn on the engine of the vehicle (30). Or it can be controlled to be off.

In the conventional digital key-related technology, it was inevitable to disassemble the provided digital key (FOB key) in order to remotely control the vehicle, and there were also limitations in that network communication between the user terminal and the server was essential. In addition, only functions such as the vehicle's doors and lights could be controlled, and starting was not possible due to manufacturer policy. However, the present invention stores the digital key in a bolt device without the need to dismantle the digital key (FOB key), and installs this bolt device on the vehicle to remotely control functions such as doors and lights, and network communication. Even in this difficult environment, control is possible through user authentication without difficulty, and once user authentication is completed, the ignition is controlled using the digital key stored in the bolt device, allowing the use of the digital key within the scope of the manufacturer's policy.

Figure 7 is a diagram for explaining a vehicle control system based on a virtual code for authentication according to another embodiment of the present invention.

Figure 8 is a flow chart of a vehicle control method based on a virtual code for authentication according to another embodiment of the present invention.

As shown in FIG. 7, the vehicle control system includes an application 10, a service server 20, and a vehicle 30.

Since the application 10 and the service server 20 are the same as those described with reference to FIG. 1, detailed description will be omitted.

The vehicle 30 is a vehicle rented by a user for a specific period (rental period), and the vehicle 30 may include a signal output control device 34 and an OBD terminal 36. Since the OBD terminal 36 is the same as that described with reference to FIG. 1, detailed description will be omitted. At this time, the signal output control device 34 may mean the same device as the signal output control device 34 described above. A detailed description of the signal output control device 34 is the same as that described with reference to FIGS. 1 to 6 and will therefore be omitted.

The signal output control device 34 is a device installed inside the vehicle 30 and connected to the OBD terminal 36. The signal output control device 34 has a digital key (more specifically, a FOB key) inside. It can be stored in its original form (i.e. without disassembling the FOB key).

At this time, the signal output control device 34 can communicate with the application 10 and the service server 20 through a communication network (not shown). At this time, various types of communication networks (not shown) may be used, such as WLAN (Wireless LAN), Wi-Fi, Wibro, Wimax, and HSDPA (High Speed Downlink Packet Access). ) or wired communication methods such as Ethernet, xDSL (ADSL, VDSL), HFC (Hybrid Fiber Coax), FTTC (Fiber to The Curb), and FTTH (Fiber To The Home) can be used. there is.

Meanwhile, the communication network (not shown) is not limited to the communication methods presented above, and may include all types of communication methods that are widely known or will be developed in the future in addition to the communication methods described above.

The signal output control device 34 may perform verification of the control request from the application 10 and determine whether to release the external connection blocking operation based on the verification result.

At this time, the verification is performed in different ways when communication is possible between the user terminal on which the application 10 is installed and the service server 20 and when communication is not possible between the user terminal and the service server 20. .

Depending on the embodiment, when communication is possible between the application 10 and the service server 20, it is generated by the service server 20 and provided to each of the application 10 and the signal output control device 34. Virtual code for authentication (the virtual code for authentication generated by the service server and provided to the application is called the first authentication virtual code, and the virtual code for authentication generated by the service server and provided to the signal output control device is called the second authentication virtual code) Verification can be performed based on Since the detailed description of this is the same as described above, it will be omitted.

Depending on the embodiment, when communication between the application 10 and the service server 20 is impossible, verification is performed based on the virtual code for authentication generated by the application 10 and provided to the signal output control device 34. This can be done. Since the detailed description of this is the same as described above, it will be omitted.

When verification is completed, the signal output control device 34 may determine whether to release the connection blocking operation of the signal output control device to the outside according to the verification result. In other words, although it has been described above as determining whether to open or close the door according to the verification result, in the system of this embodiment, when verification by the signal output control device 34 is completed, a connection blocking operation with the outside (jamming operation or It may be determined whether to release the battery power cutoff operation.

Depending on the embodiment, when the operation to block external connection is canceled, the vehicle may be controlled based on a control signal from the application 10. For example, when the application 10 requests opening the door of a vehicle, the door of the vehicle may be opened when the operation of blocking connection with the outside is canceled.

Depending on the embodiment, the signal output control device 34 is connected to the OBD terminal 36 inside the vehicle, and if the verification is successful, the CAN data related to door control can be input to the OBD terminal to control the vehicle. there is.

For example, if the verification is successful, the signal output control device 34 can open and close the door of the vehicle by inputting CAN data related to door opening and closing to the OBD terminal.

In the above, a method of controlling a vehicle through user authentication was described when a user who has rented a vehicle directly uses the vehicle. Below, we will describe a vehicle control method through user authentication when a rented vehicle is used by someone other than the user.

Cases of use by others include cases where the vehicle rented by the user is used by the user's family, cases where valet services are provided for a vehicle rented by the user, and cases where valet services are provided for a vehicle owned by the user. It may include, but is not limited to this.

According to the embodiment, when the same application as the application installed by the user is installed on the terminal used by another person, the user provides the virtual code for authentication generated in the user's application to the other person's application, so that the other person can use the vehicle You can make it available for use. At this time, the user and another person's terminal can transmit and receive signals or information through short-distance communication such as Bluetooth, but the communication method is not limited to this.

The virtual code for authentication received through another person's application is provided to the vehicle on-off control device (or signal output device) of the vehicle, so that verification of the virtual code for authentication can be performed. And by performing user authentication through verification, the other person can use the vehicle. Since the generation and verification method for the virtual code for authentication is the same as described above, detailed description is omitted.

At this time, the virtual code for authentication generated in the user's application may include a fixed virtual code and expiration date information. Different fixed virtual codes are generated depending on the type of use (i.e., for valet, family, corporate, etc.), and an expiration date for each fixed virtual code can be set. For example, when a user creates a virtual code for authentication for valet use, others who have received the virtual code for authentication can use the virtual code for authentication and use the vehicle only during the validity period (e.g., 3 hours). It becomes possible.

According to the embodiment, if the same application as the application installed by the user is not installed on the terminal used by another person, the user provides the registered blank card to the other person, and the other person uses the blank card to use the vehicle through NFC tagging. can be used.

Here, the registered blank card refers to a blank card that has been granted permission to request control of the vehicle through the user's application. The vehicle on/off control device (or signal output control device) can receive the control request from the authorized blank card through NFC tagging.

As described above, when registering a blank card, an expiration date for the blank card can be set, and when the validity period expires, vehicle use using the blank card becomes impossible.

That is, when the other person tags the blank card provided by the user through the NFC reader attached to the vehicle (for example, on the side of the windshield), the vehicle on-off control device (or signal output control device) inside the vehicle is activated. A virtual code for authentication can be generated and verified based on the blank card-related information received from the NFC reader. In other words, it verifies whether it is a registered blank card. Since the generation and verification method for the virtual code for authentication is the same as described above, detailed description is omitted.

More specifically, the user can keep at least one blank card inside the vehicle and register the blank card in his or her application whenever necessary (whenever using valet). Then, the vehicle on/off control device inside the vehicle generates a virtual code for authentication based on the blank card information (serial number, etc.) received through NFC tagging and verifies it, so that the blank card is used by the user. It is possible to determine whether the card is registered for the vehicle.

For example, if the application is not installed on the terminal of the parking attendant performing valet parking, a digital key must be handed over to perform valet parking, and in this case, vehicle theft may occur. Therefore, in the present invention, a blank card with the expiration date set above is provided to the parking attendant instead of a digital key, thereby allowing the parking attendant to use the vehicle only for a limited time.

2 and 8 illustrate that steps S110 to S140 and steps S210 to S230 are sequentially executed, but this is merely an illustrative explanation of the technical idea of this embodiment, and is commonly used in the technical field to which this embodiment belongs. Anyone with knowledge can change the order shown in FIGS. 2 and 8 without departing from the essential characteristics of the present embodiment, or execute one or more of steps S110 to S140 and steps S210 to S230 in parallel. Since it can be applied with various modifications and modifications, FIGS. 2 and 8 are not limited to the time series order.

The method according to an embodiment of the present invention described above may be implemented as a program (or application) and stored in a medium in order to be executed in combination with a computer, which is hardware. Here, the computer may be the device 10 described above.

The above-mentioned program is C, C++, JAVA, machine language, etc. that can be read by the processor (CPU) of the computer through the device interface of the computer in order for the computer to read the program and execute the methods implemented in the program. It may include code coded in a computer language. These codes may include functional codes related to functions that define the necessary functions for executing the methods, and include control codes related to execution procedures necessary for the computer's processor to execute the functions according to predetermined procedures. can do. In addition, these codes may further include memory reference-related codes that indicate at which location (address address) in the computer's internal or external memory additional information or media required for the computer's processor to execute the above functions should be referenced. there is. In addition, if the computer's processor needs to communicate with any other remote computer or server in order to execute the above functions, the code uses the computer's communication module to determine how to communicate with any other remote computer or server. It may further include communication-related codes regarding whether communication should be performed and what information or media should be transmitted and received during communication.

The steps of the method or algorithm described in connection with embodiments of the present invention may be implemented directly in hardware, implemented as a software module executed by hardware, or a combination thereof. The software module may be RAM (Random Access Memory), ROM (Read Only Memory), EPROM (Erasable Programmable ROM), EEPROM (Electrically Erasable Programmable ROM), Flash Memory, hard disk, removable disk, CD-ROM, or It may reside on any type of computer-readable recording medium well known in the art to which the present invention pertains.

Above, embodiments of the present invention have been described with reference to the attached drawings, but those skilled in the art will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. You will be able to understand it. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

10: Application
20: Service server
30: vehicle

Claims (19)

An application installed on the terminal of a user using a car rental service;
When a control request for a vehicle door is received from the application, a vehicle on/off control device that performs verification of the control request and controls opening and closing of the vehicle door according to the verification result; and
A signal output control device that cancels the connection blocking operation with the outside when information about the opening and closing of the door of the vehicle is received from the vehicle on-off control device,
The signal output control device includes a digital key of the vehicle therein,
When the external connection blocking operation is released, the digital key controls the starting of the vehicle,
Vehicle control system based on virtual code for authentication. According to claim 1,
The operation of blocking the connection with the outside includes the operation of blocking the signal output from the vehicle from being transmitted to the inside of the signal output control device and the operation of blocking power from being supplied to the digital key.
Vehicle control system based on virtual code for authentication. According to claim 1,
The above verification is,
If communication is possible between the user's terminal and the service server providing the vehicle rental service, it is performed based on the virtual code for authentication generated by the service server and provided to each of the application and the vehicle on-off control device,
If communication between the user's terminal and the service server is impossible, the authentication is performed based on the virtual code generated by the application.
Vehicle control system based on virtual code for authentication. According to claim 1,
The vehicle on-off control device,
Receiving from the application a first authentication virtual code generated by a service server providing the vehicle rental service and provided to the application,
Determine whether there is a match between the first virtual code for authentication and the second virtual code for authentication generated by the service server and received from the service server,
If it is determined that the first virtual code for authentication and the second virtual code for authentication match, allowing opening and closing of the door of the vehicle,
Vehicle control system based on virtual code for authentication. According to claim 1,
The vehicle on-off control device,
Receive the virtual code for authentication generated by the application,
Search for user identification information based on the virtual code for authentication,
Extract the stored authority information matching the searched user identification information,
Allowing opening and closing of the door of the vehicle only when the virtual code for authentication is received within the time range corresponding to the extracted authority information,
Vehicle control system based on virtual code for authentication. According to clause 5,
The vehicle on-off control device,
Determining the virtual code for authentication as a normal code only when the generation time when the virtual code for authentication is generated by the application and the reception time when the virtual code for authentication is received from the application are within an error range,
Vehicle control system based on virtual code for authentication. According to claim 1,
The vehicle on-off control device,
If the verification is successful, the distance between the application and the vehicle is determined based on the strength of the signal according to the control request,
Transmitting information about the opening and closing of the door of the vehicle to the signal output control device when the determined distance is within a preset distance,
Vehicle control system based on virtual code for authentication. According to clause 7,
In an external connection blocking operation state for the signal output control device, the first signal sent by the vehicle is blocked and the first signal is not transmitted to the digital key,
When it is determined to cancel the external connection blocking operation for the signal output control device, the first signal sent by the vehicle is transmitted to the digital key, and the digital key outputs a second signal in response to the first signal. to control the starting of the vehicle on or off,
Vehicle control system based on virtual code for authentication. According to claim 1,
The vehicle on-off control device,
It is connected to the OBD terminal inside the vehicle, and if the verification is successful, CAN data related to door opening and closing is input to the OBD terminal to open and close the door of the vehicle.
Vehicle control system based on virtual code for authentication. According to claim 1,
The application grants authority for the control request to at least one empty card,
The vehicle on-off control device receives the control request from the at least one blank card through NFC tagging,
Vehicle control system based on virtual code for authentication. An application installed on the terminal of a user using a car rental service; and
When a control request for the vehicle is received from the application, a signal output control device performs verification of the control request and cancels the external connection blocking operation according to the verification result,
The signal output control device includes a digital key of the vehicle therein,
Vehicle control system based on virtual code for authentication. According to claim 11,
The operation of blocking the connection with the outside includes the operation of blocking the signal output from the vehicle from being transmitted to the inside of the signal output control device and the operation of blocking power from being supplied to the digital key,
Vehicle control system based on virtual code for authentication. According to claim 11,
The above verification is,
If communication is possible between the user's terminal and the service server providing the vehicle rental service, it is performed based on the virtual code for authentication generated by the service server and provided to each of the application and the signal output control device,
If communication between the user's terminal and the service server is impossible, the authentication is performed based on the virtual code generated by the application.
Vehicle control system based on virtual code for authentication. According to claim 11,
The signal output control device,
Receiving from the application a first authentication virtual code generated by a service server providing the vehicle rental service and provided to the application,
Determine whether there is a match between the first virtual code for authentication and the second virtual code for authentication generated by the service server and received from the service server,
If it is determined that the first virtual code for authentication and the second virtual code for authentication match, canceling the blocking operation of the external connection,
Vehicle control system based on virtual code for authentication. According to claim 11,
The signal output control device,
Receive the virtual code for authentication generated by the application,
Search for user identification information based on the virtual code for authentication,
Extract the stored authority information matching the searched user identification information,
Releasing the blocking operation of the external connection only when the virtual code for authentication is received within the time range corresponding to the extracted authority information,
Vehicle control system based on virtual code for authentication. According to claim 15,
The signal output control device,
Determining the virtual code for authentication as a normal code only when the generation time when the virtual code for authentication is generated by the application and the reception time when the virtual code for authentication is received from the application are within an error range,
Vehicle control system based on virtual code for authentication. According to claim 11,
The signal output control device,
If the verification is successful, the distance between the application and the vehicle is determined based on the strength of the signal according to the control request,
If the determined distance is within a preset distance, canceling the external connection blocking operation,
Vehicle control system based on virtual code for authentication. According to claim 11,
The signal output control device,
It is connected to the OBD terminal inside the vehicle, and if the verification is successful, CAN data related to door opening and closing is input to the OBD terminal to open and close the door of the vehicle.
Vehicle control system based on virtual code for authentication. According to claim 11,
The application grants authority for the control request to at least one empty card,
The signal output control device receives the control request from the at least one blank card through NFC tagging,
Vehicle control system based on virtual code for authentication.

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