KR20170134862A - Vehicle Loading Adaptive Radio Signal Device for Broadcasting Asynchronous Radio Signal - Google Patents

Abstract

The present invention relates to a vehicle-mounted adaptive signal device for transmitting an asynchronous radio signal. According to the present invention, the vehicle-mounted adaptive signal device for transmitting an asynchronous radio signal, capable of supplying power of a vehicle, comprises: a power supply unit receiving power supplied from the vehicle; a power conversion unit converting the power supplied from the vehicle into designated operation power; and a chip module operating through the operation power which is converted from the vehicle power supplied from the vehicle when power supply from the vehicle is confirmed through the power supply unit, processing at least one bidirectional data communication including Wi-Fi communication with a paired user terminal, and broadcasting an asynchronous radio signal to the outside by using the vehicle power.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a vehicle-mounted adaptive signal device for transmitting an asynchronous radio signal,

The present invention provides a chip module for providing WiFi communication to a signal device mounted on a vehicle and capable of supplying vehicle power to transmit a basic set asynchronous radio signal for providing a designated service in a designated space, When an asynchronous radio signal is amplified and transmitted through a vehicle power supply, if the vehicle is not supplied with power, an asynchronous radio signal is transmitted in a low power mode using a charging power source. In addition to the basic asynchronous radio signal, And to provide an in-vehicle adaptive signaling device for selectively controlling an asynchronous radio signal to be broadcast.

An asynchronous radio signal service is provided that incorporates a chip module in a designated vehicle-mounted signal device mounted on a vehicle to provide identification / authentication or membership services in a designated space (e.g., a department store, an apartment, a building, a designated parking lot).

On the other hand, when a chip module for transmitting an asynchronous radio signal to a signal device for the asynchronous radio signal service is provided, the asynchronous radio signal transmitted from the chip module is difficult to be transmitted to the outside of the vehicle. The position where the vehicle-mounted signal device is mounted on the vehicle is a position where electromagnetic interference of various electronic devices provided in the vehicle is severe. In particular, a metal material of a frame or a vehicle body of a vehicle, a glass material of a window, The asynchronous radio signal is transmitted to the outside of the vehicle. In addition, when the chip module operates in a low energy mode, it is more difficult to transmit an asynchronous radio signal to the outside of the vehicle in the low power mode.

On the other hand, when the chip module is mounted on the signal device for the asynchronous radio signal service described above, the asynchronous radio signal can be recognized only through the signal receiver provided in the predetermined space to provide the predetermined service, Even if it is possible to receive the asynchronous radio signal, it is difficult to recognize the information in the unspecified space (for example, the space provided with the signal receiver recognizing the asynchronous radio signal of the chip module). Generally, in order to solve such a problem, a signal receiver provided in an unspecified space is corrected or a signal receiver provided in an unspecified space is connected to a network to remotely control the problem. In this case, And it is costly to build / modify the infrastructure.

In order to solve the above-mentioned problems, an object of the present invention is to provide a power supply apparatus, comprising: a power supply unit supplied with power from a vehicle; a power conversion unit converting power supplied from the vehicle into a specified operation power; The method comprising the steps of: operating via an operating power source that converts vehicle power supplied from the vehicle when power is supplied from the vehicle; and processing at least one bi-directional data communication involving WiFi communication with the paired user terminal, And an asynchronous radio signal having a chip module for broadcasting an asynchronous radio signal to the outside.

An on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention is an on-vehicle signaling device capable of supplying power to a vehicle. The onboard signaling device includes a power supply part supplied with power from a vehicle, To a designated operation power source, and an operation power source that converts vehicle power supplied from the vehicle when the power supply from the vehicle is confirmed through the power supply unit, and performs a WiFi communication with the paired user terminal And a chip module for processing at least one bi-directional data communication including the at least one bi-directional data communication and broadcasting the asynchronous radio signal to the outside using the vehicle power source.

The on-vehicle adaptive signaling apparatus for transmitting an asynchronous radio signal according to the present invention may further include a power charging unit for charging at least one of a power source supplied through the power supply unit or a power source converted through the power conversion unit And the chip module operates using the charging power source charged in the power charging unit when power supply of the vehicle is not confirmed.

The on-vehicle adaptive signaling apparatus for transmitting an asynchronous radio signal according to the present invention may further include a USB connector unit including a USB connector for externally applying a USB (Universal Serial Bus) power converted through the power converter unit .

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module is provided with a USB communication unit electrically connected to the USB connector unit to process USB-based data communication .

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module performs bidirectional USB-based data communication with the user terminal when the user terminal is connected to the USB connector unit .

The present invention also provides an adaptive signaling device for on-board transmission of an asynchronous radio signal according to the present invention, wherein the chip module operates through a vehicle power supplied from a vehicle and, when bidirectional short- And a USB control unit for deactivating communication.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module may include an identification information storage area for storing terminal identification information for uniquely identifying and authenticating a user terminal (or a program of a user terminal) And a terminal registration unit for receiving the terminal identification information from the user terminal and registering the terminal identification information in the identification information storage area when bidirectional data communication is established with the user terminal.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module may transmit bidirectional data using the terminal identification information when a bidirectional data communication connection is established with the user terminal, A terminal authentication unit for authenticating the validity of the communication-connected user terminal (or the program of the user terminal), and a communication processing unit for processing bi-directional data communication with the terminal authenticated through the terminal identification information.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module may include a memory unit having a PIN storage area for storing PIN authentication information for PIN authentication, A PIN registration unit for registering PIN authentication information from the terminal and storing the PIN authentication information in the PIN storage area and a PIN authentication unit for receiving the PIN information input through the user terminal connected to the bidirectional data communication and authenticating the PIN information through the PIN authentication information .

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module includes a basic setting memory area for storing a data set for broadcasting a basic asynchronous radio signal, And a memory unit having a use definition memory area for storing a data set for broadcasting the defined asynchronous radio signal.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module includes an information storage unit for storing unique information to be broadcast on a predetermined asynchronous radio signal in a designated basic setting memory area, And a signal transmission unit for controlling the asynchronous radio signal including the unique information of the basic setting memory area to be broadcasted.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module may transmit one or more fixed seed values for generating a one-time code to be broadcast through a predetermined asynchronous radio signal, A seed determining unit for determining at least one dynamic seed value for generating the disposable code, and a seed determining unit for assigning at least one fixed seed value and at least one dynamic seed value to the designated code generating algorithm, And a signal transmission unit for controlling the broadcasting of the asynchronous radio signal including the disposable code.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module includes an information storage unit for storing unique information to be broadcast through a predetermined asynchronous radio signal in a designated basic setting memory area, A seed storage unit for storing at least one fixed seed value for generating a one-time code for broadcasting through a set asynchronous radio signal in the basic setting memory area, and a seed determination unit for determining at least one dynamic seed value for generating the one- Comprising: a code generation unit for dynamically generating a one-off code by substituting one or more fixed seed values and at least one dynamic seed value into a designated code generation algorithm and an asynchronous radio signal including unique information of the basic setting memory region and the one- And a signal transmitting unit for controlling the broadcasting .

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module includes: a power source confirmation unit for confirming a state of supplying vehicle power from the vehicle; And a mode setting unit for setting or confirming the vehicle power supply mode to be operated by using the charging power supply unit and confirming or confirming the charging power supply mode operated by using the charging power supply unit when the vehicle power supply is not confirmed. do.

The on-chip adaptive signaling device for transmitting an asynchronous radio signal according to the present invention is characterized in that the chip module amplifies the asynchronous radio signal to a maximum output of a pre-calculated output or an available range in operation, And a signal control unit for controlling the broadcast signal to be broadcast.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module may include a signal for controlling the asynchronous radio signal to be broadcast at a low power output And a control unit.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module receives setting information for selectively broadcasting a use-defined asynchronous radio signal from a user terminal through bidirectional data communication And a transmission control unit for controlling to broadcast a usage-defined asynchronous radio signal corresponding to the setting information.

In the in-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the setting information includes unique information to be included in the asynchronous radio signal for use definition, a seed value for generating a one- , And a protocol structure of a usage definition asynchronous radio signal.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module includes an information storage unit for storing the unique information included in the setting information in a designated usage definition memory area, And a signal transmission unit for controlling the broadcast of the usage definition asynchronous radio signal including the unique information stored in the area.

The chip module may further include a seed storage unit for storing one or more seed values included in the setting information in a designated usage definition memory area, A code generation unit for dynamically generating a one-time code by substituting one or more seed values into a seed determination unit for determining one or more seed values for generating a code and a specified code generation algorithm, and a use definition asynchronous radio signal including the one- And a signal transmitting unit for controlling the broadcasting unit to broadcast.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the chip module may include an information storage unit for storing the unique information included in the setting information in a designated usage definition memory area, A seed determining unit for determining one or more seed values for generating the one-time use code, and a seed value assigning unit for assigning one or more seed values to the designated code generating algorithm, And a signal transmission unit for controlling the broadcasting of the asynchronous radio signal including the unique information stored in the usage definition memory area and the generated one-time code.

In the on-vehicle adaptive signaling apparatus for transmitting an asynchronous radio signal according to the present invention, the dispatch control unit determines whether to broadcast a use-defined asynchronous radio signal according to a control command of a user terminal connected with bidirectional data communication .

In the on-vehicle adaptive signaling apparatus for transmitting an asynchronous radio signal according to the present invention, the transmission control unit can not perform bidirectional short-range wireless communication with the user terminal in a state where effective setting information is stored in a designated usage definition memory area And determines whether to broadcast a usage definition asynchronous radio signal based on whether or not the asynchronous radio signal is broadcast.

In the on-vehicle adaptive signaling device for transmitting an asynchronous radio signal according to the present invention, the transmission control section controls to broadcast the application-defined asynchronous radio signal while the effective setting information is stored in the designated usage definition memory area, Defined asynchronous radio signal is not broadcast when a predetermined time elapses or when a specific signal is received from the user terminal.

In the above-described adaptive signaling device for on-board transmission of an asynchronous radio signal according to the present invention, the communication processing unit may transmit, to the user terminal via bidirectional data communication, one of the asynchronous radio signal and the asynchronous radio signal, And provides signal transmission information corresponding to a state of broadcasting a radio signal.

According to the present invention, a chip module is embedded in a signal device that is mounted on a vehicle and supplied with vehicle power, stably broadcasts an asynchronous radio signal to the outside of the vehicle, and identifies the user in a designated space (e.g., a department store, an apartment building, / Asynchronous radio signal services such as authentication and membership services are provided.

According to the present invention, the signal device is used as a power supply device when the vehicle power is connected to the signal device, and when the signal device is disconnected from the vehicle power, the chip module is controlled using the user's terminal, There is an advantage to apply to the service in real time.

According to the present invention, there is provided a signal receiver for receiving an asynchronous radio signal of a chip module by controlling a chip module of a signaling device through a user terminal to broadcast an asynchronous radio signal defined for a specific purpose besides a basic asynchronous radio signal It is advantageous to provide an asynchronous radio signal service adaptable in real time without modifying it to recognize an asynchronous radio signal set in the chip module or connecting it to a network and remotely controlling it.

1 is a diagram showing the configuration of an in-vehicle adaptive signaling device 100 according to an embodiment of the present invention.
2 is a diagram showing the configuration of the chip module 200 of the signaling device 100 according to an embodiment of the present invention.
3 is a functional block diagram of a user terminal 300 and a program 325 according to an embodiment of the present invention.
4 is a diagram illustrating a mode setting / checking process of the chip module 200 according to an embodiment of the present invention.
5 is a diagram illustrating a process of registering terminal identification information and chip module identification information according to an embodiment of the present invention.
6 is a diagram illustrating a process of authenticating the terminal 300 or authenticating the chip module 200 according to an embodiment of the present invention.
7 is a diagram illustrating an asynchronous radio signal broadcasting process of the chip module 200 according to the first embodiment of the present invention.
8 is a diagram illustrating an asynchronous radio signal broadcasting process of the chip module 200 according to the second embodiment of the present invention.
9 is a diagram illustrating an asynchronous radio signal broadcasting process of the chip module 200 according to the third embodiment of the present invention.
10 is a diagram illustrating a process of providing setting information for broadcasting a usage definition asynchronous radio signal according to an embodiment of the present invention.
11 is a diagram illustrating a process of selectively activating / deactivating bi-directional USB data communication functions of the chip module 200 according to an embodiment of the present invention.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. It should be understood, however, that the drawings and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention, and are not to be construed as limiting the present invention.

In other words, the following embodiments correspond to the preferred embodiment of the preferred embodiment of the present invention. In the following embodiments, a specific configuration (or step) is omitted, or a specific configuration (or step) (Or steps), or an embodiment that incorporates functions implemented in more than one configuration (or step) into any one configuration (or step), a particular configuration (or step) It will be apparent that the present invention is not limited to the embodiments described below. Therefore, it should be clearly stated that various embodiments corresponding to subsets or combinations based on the following embodiments can be subdivided based on the filing date of the present invention.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The terms used below are defined in consideration of the functions of the present invention, which may vary depending on the user, intention or custom of the operator. Therefore, the definition should be based on the contents throughout the present invention.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are merely means for effectively explaining the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs Only.

1 is a diagram showing the configuration of a vehicle-mounted adaptive signaling device 100 according to an embodiment of the present invention.

1 is a block diagram illustrating an asynchronous radio signal transmission system according to a first embodiment of the present invention. Referring to FIG. 1, a chip module 200 is mounted on a signal device 100 capable of supplying power to a vehicle. (E.g., an asynchronous radio signal in a low power mode) using a power source charged through a vehicle power source when the power of the vehicle is not supplied to the vehicle 1 is a block diagram illustrating a configuration of a signaling device 100 according to an embodiment of the present invention. Referring to FIG. 1 and / or modified by those skilled in the art, various implementations of the signaling device 100 For example, some implementations may be omitted, or subdivided, or aggregated implementations), but the present invention contemplates all of the above enumerated implementations. And the technical features thereof are not limited only by the method shown in FIG.

The vehicle-mounted signal device 100 of the present invention includes a body portion 105 which can be mounted on a vehicle and has a body capable of supplying power to the vehicle, and a vehicle power source (for example, a 12 V DC power source) And a chip module (200) having a power supply unit (115) to receive and bidirectionally communicate the predetermined user terminal (300) specified in the body or to broadcast a predetermined asynchronous radio signal to the outside, and the chip module (Not shown) for operating the operation of the operation unit 200 (not shown).

According to the method of the present invention, the vehicle-mounted signal device 100 can be mounted on the vehicle at one of the basic configuration and optional configuration of the vehicle at the time of manufacture of the vehicle, The device 100 may be purchased (or provided) and mounted on the user's vehicle in a form of connecting the vehicle's power source. The vehicle-mounted signal device 100 of the present invention may be any device that is mounted on a vehicle and can receive vehicle power, (100). For example, the signaling device 100 may include various devices such as a cigar jack device inserted into a cigar jack inlet of a vehicle, an OBD device inserted into an OBD-II port of a vehicle, and a navigation device powered by a vehicle. Hereinafter, the vehicle-mounted signaling apparatus 100 will be described as 'signaling apparatus 100' for the sake of convenience.

The body 105 can be mounted in the interior of the vehicle or in the interior of the vehicle and has a trunk structure capable of supplying power to the vehicle. The trunk 105 can be a vehicle power source (for example, 12V A terminal 110 connected to a power contact point of a cigar jack insertion port of a vehicle or a terminal 110 connected to a power contact point of a OBD-II port of a vehicle (= pin 16) Etc.). The body structure of the signal device 100 may have any structure (or shape) as long as it is mounted on the vehicle and can receive power from the vehicle, and is not limited to a specific structure (or shape).

The power supply unit 115 is a collective term for being electrically connected to a terminal 110 provided in the body 105 to receive vehicle power. When the signal system 100 is mounted on a vehicle, 105 are electrically connected to an in-vehicle contact supplying vehicle power.

1, the signaling device 100 includes a power conversion unit 120 that converts power supplied from the vehicle to at least one designated operation power source, A USB connector 125 for applying a universal serial bus (" USB ") power to the outside, and a power supply for supplying at least one of power supplied through the power supply unit 115 or power converted through the power conversion unit 120 And a power source for supplying power from at least one of a vehicle power source supplied from the vehicle and a charging power source charged in the power charging unit 130, and outputs an asynchronous radio signal according to at least one radio signal standard to the outside And a chip module 200 for transmitting (broadcasting)

The asynchronous radio signal according to the embodiment of the present invention can be transmitted to a transmitting side that transmits a radio signal of a specified standard and a receiving side that receives the radio signal in advance without pairing or identifying / (= Broadcast) a radio signal including information of a designated data structure to be transmitted, receives the asynchronous radio signal transmitted from the unspecified receiver, and transmits the asynchronous radio signal to the non- At least one designated receiver capable of reading the data structure can recognize and use the information of the designated data structure included in the asynchronous radio signal. That is, the transmitting side transmits information (= broadcasting) including the information of the data structure specified in the asynchronous radio signal of the specified standard that can be received at the unspecified receiving side without specifying or identifying the receiving side in advance, and transmits the asynchronous radio signal The information included in the asynchronous radio signal can be recognized and used only by at least one designated receiving side that can read the information included in the asynchronous radio signal from the receiving side. The asynchronous radio signal according to an exemplary embodiment of the present invention may include an asynchronous radio signal based on a WiFi standard. However, the asynchronous wakeup signal of the present invention is not limited to the asynchronous wireless signal based on the Wi-Fi standard, and it is obvious that it can include asynchronous wireless signals of various standards (for example, Bluetooth 4.0 standard) according to the intention of the person skilled in the art I will.

The electrical characteristics (e.g., voltage, current, etc.) of the vehicle power supplied through the power supply unit 115 may be different from the operating power of the USB power supply and / or the chip module 200. For example, the vehicle power source may be DC 12V and the USB power source may be DC 5V. The power conversion unit 120 converts the electrical characteristics of the vehicle power supplied through the power supply unit 115 into a USB power and / or a power corresponding to the operation of the chip module 200.

The USB connector unit 125 includes a connector that is exposed (or opens a predetermined cover and is exposed to the outside), and externally applies the USB power converted through the power converter unit 120 through the connector.

The power charging unit 130 charges at least one of the power supplied from the vehicle through the power supply unit 115 or the power converted through the power conversion unit 120. The power charging unit 130 charges the power required for the low power mode operation of the chip module 200. For example, the power charging unit 130 may include a battery or a super capacitor.

The chip module 200 is a general term for a module (or a combination of components) for transmitting an asynchronous radio signal to be transmitted (or broadcast) without specifying a receiving side. The chip module 200 includes a power supply unit 130, (Or broadcasting) an asynchronous radio signal by using any one of the vehicle power and the charging power. For example, the asynchronous radio signal may comprise a Wi-Fi based asynchronous radio signal. However, the asynchronous radio signal of the present invention is not limited to the Wi-Fi based asynchronous radio signal. If the asynchronous radio signal is transmitted without a separate pairing or mutual authentication and is received or recognized by a nearby receiver, I clarify it clearly.

When the power supply from the vehicle is confirmed through the power supply unit 115, the chip module 200 can operate through the vehicle power supplied from the vehicle. If the power supply of the vehicle is not confirmed, And can operate using the charging power source charged in the power charging unit 130. [

The chip module 200 is connected to the user terminal 300 in a bidirectional short-range wireless communication mode when the short-range wireless communication function (e.g., Wi-Fi communication function, etc.) of the user terminal 300 that has undergone separate pairing or mutual identification / Way USB data communication with the user terminal 300 when the user terminal 300 that has undergone pairing or mutual identification / authentication is connected to the USB connector 125 . Meanwhile, the chip module 200 can process asynchronous radio signal transmission (broadcast) with at least one of bi-directional short-range wireless communication and / or bidirectional USB data communication.

According to the method of the present invention, when the vehicle power is supplied through the power supply unit 115 (or the vehicle power is converted through the power conversion unit 120), the chip module 200 is supplied with power And may operate using a power source (e.g., vehicle power supplied through the power supply unit 115, or vehicle power converted through the power conversion unit 120).

Alternatively, when no vehicle power is supplied to the power supply unit 115 (for example, when the terminal 110 of the trunk unit 105 is disconnected from the vehicle power supply, or when the vehicle is not turned on due to the ignition of the vehicle, ), The chip module 200 operates using the charging power source charged in the power charging unit 130. Preferably, the chip module 200 may operate in a BLE (Bluetooth Low Energy) mode using a power source charged in the power charging unit 130.

According to an embodiment of the present invention, the chip module 200 identifies / authenticates the vehicle or the user identity driving the vehicle in a designated space (for example, a department store, an apartment, a building, a designated parking lot) Or to broadcast a predetermined asynchronous radio signal to identify / authenticate the membership service to be provided to the user in the designated space.

Meanwhile, when the local wireless communication function (e.g., Wi-Fi communication function) of the user terminal 300 is activated, the chip module 200 paired with the user terminal 300, (E.g., two-way Wi-Fi data communication, etc.) and receive valid configuration information defining the use of the asynchronous radio signal from the paired user terminal 300 via bidirectional short-range wireless communication . If valid setting information is received from the paired user terminal 300 through bidirectional short-range wireless communication, the chip module 200 may transmit the asynchronous radio signal, which is defined by the setting information in place of the basic asynchronous radio signal, . ≪ / RTI >

Or when the user terminal 300 is connected to the USB connector unit 125 through a cable, the chip module 200 may transmit the user terminal 300, which is connected to the USB connector unit 125, And can receive valid setting information defining the use of the asynchronous radio signal from the user terminal 300 through bidirectional USB data communication. If valid setting information is received through the bidirectional USB data communication from the paired user terminal 300, the chip module 200 may transmit the asynchronous radio signal, which is defined by the setting information in place of the basic asynchronous radio signal, . ≪ / RTI >

If the configuration information received from the user terminal 300 is not confirmed through at least one of bidirectional short-range wireless communication and bi-directional USB data communication, or is invalid even though the setting information is confirmed, 200 can broadcast the asynchronous radio signal with the default setting.

2 is a diagram showing a configuration of a chip module 200 of a signaling device 100 according to an embodiment of the present invention.

2, the chip module 200 includes a control unit 220 for controlling the operation of the chip module 200, and a control unit 220 for storing a data set (or program code) necessary for the operation of the chip module 200 An RF processor 212 for performing RF processing for bi-directional short-range wireless communication or asynchronous radio signal broadcasting, a memory unit 208 for transmitting / receiving a radio frequency signal for bidirectional short- And a USB communication unit 204 that is electrically connected to the USB connector unit 125 and processes bi-directional USB data communication.

The chip module 200 is manufactured in the form of one or more chips or SMD (Surface Mount Devices) for transmitting an asynchronous radio signal to a PCB (Printed Circuit Board), and the control unit 220, the memory unit 208, And the RF processor 212 may be implemented in the form of an integrated chip or an individual device mounted on a PCB or a combination of an integrated chip and each device.

The control unit 220 is a general term for controlling the operation of the chip module 200. The control unit 220 includes at least one processor and an execution memory, BUS). According to the present invention, the control unit 220 loads at least one program code included in the chip module 200 into the execution memory through the processor, and outputs the result through at least one configuration And controls the operation of the chip module 200. [0031] FIG. Hereinafter, a program structure implemented in the chip module 200 in the form of a program code will be described in the control unit 220 for convenience.

The memory unit 208 is a general term of a nonvolatile memory included in the chip module 200 and includes at least one program code executed through the control unit 220 and at least one data set used by the program code And stores it. The memory unit 208 basically stores a system program code and a system data set corresponding to the operating system of the chip module 200 and at least one application program code and an application data set, The program code and data set are also stored in the memory unit 208.

According to an embodiment of the present invention, the memory unit 208 may include a basic memory area for storing a data set for broadcasting a basic asynchronous radio signal.

According to an embodiment of the present invention, the memory unit 208 stores a data set for broadcasting an asynchronous radio signal that is defined by use of configuration information received through at least one bidirectional data communication from the user terminal 300 A usage definition memory area may be provided.

According to the embodiment of the present invention, the memory unit 208 may include a PIN storage area for storing PIN authentication information for performing a Personal Identification Number (PIN) authentication procedure.

According to the method of the present invention, the memory unit 208 may store terminal identification information that uniquely identifies the paired user terminal 300 for bi-directional short-range wireless communication and / And an identification information storage area for storing identification information.

According to the embodiment of the present invention, the memory unit 208 may store chip module identification information for allowing the user terminal 300 to uniquely identify and authenticate the chip module 200.

The RF processor 212 is a generic term for performing RF processing (e.g., radio frequency signal modulation, etc.) for transmitting and receiving a radio frequency signal through the antenna unit 216. The RF processor 212 includes an asynchronous radio signal Performs RF processing for broadcasting (broadcasting) or performs RF processing for bi-directional short-range wireless communication (for example, bi-directional Wi-Fi data communication, etc.) with the paired user terminal 300.

The USB communication unit 204 is electrically connected to a connector (for example, D + and / or D-) provided in the USB connector unit 125 of the signal device 100, Way USB data communication with a previously registered user terminal 300 (e.g., a mobile terminal such as a user's own mobile phone, a smart phone, a tablet PC, etc.). The bi-directional USB data communication includes a USB communication function for transmitting and receiving a USB packet, and the external terminal 300 connected to the USB connector 125 detects the chip module 200 and prepares for USB communication USB protocol functionality.

According to the embodiment of the present invention, the USB communication unit 204 maintains a state of being electrically connected to the connector of the USB connector unit 125, but the bi-directional USB data communication function of the USB communication unit 204 Directional USB data communication with the terminal 300 connected to the USB connector unit 125 when the bidirectional USB data communication function of the USB communication unit 204 is activated, If the bidirectional USB data communication function of the USB communication unit 204 is disabled, the bidirectional USB data communication may not be processed even if the user terminal 300 is connected to the USB connector unit 125. [

Referring to FIG. 2, the chip module 200 includes a terminal registration unit 224 for registering effective terminal identification information of the user terminal 300 in the identification information storage area by performing a pairing procedure and / or a terminal registration procedure, A terminal authentication unit 228 for identifying and authenticating the user terminal 300 that performs at least one bi-directional data communication among bi-directional short-range wireless communication and bi-directional USB data communication using valid terminal identification information registered in the identification information storage region, And a communication processing unit 240 for processing bidirectional short-range wireless communication or bi-directional USB data communication with the user terminal 300 identified and authenticated through the terminal identification information. Meanwhile, the chip module 200 registers the PIN authentication information for PIN authentication from the user terminal 300 through at least one bidirectional data communication among the bi-directional short-range wireless communication and the bidirectional USB data communication according to the embodiment, A bidirectional data communication between the user terminal 300 corresponding to the terminal identification information registered in the identification information storage area and the bi-directional short-range wireless communication or bi-directional USB data communication, And a PIN authentication unit 236 for performing a PIN authentication process using the PIN authentication information registered in the PIN storage area, if necessary.

When the user purchases the signaling device 100 and attempts pairing between the user terminal 300 owned by the user and the chip module 200, the terminal registering part 224 registers valid terminal identification information Is registered. The chip module 200 of the signaling device 100 is manufactured by storing a NULL value or temporary information in the identification information storage area. When the user purchases the signaling device 100 and attempts to pair the signal device 100 for the first time, The valid terminal identification information is not registered. In this case, the terminal registration unit 224 performs a pairing procedure with the user terminal 300 according to a pairing procedure.

When the user installs a specific program 325 communicating with the chip module 200 of the signaling device 100 in the user terminal 300 owned by the user, the terminal registration part 224 registers the paired user terminal 300 ) Program 325 to identify the terminal identification information capable of authenticating the user terminal 300, and stores the identified terminal identification information in the identification information storage area. In this case, the terminal identification information includes information for uniquely identifying the user terminal 300, and may be unique identification authentication information up to the program 325 installed in the user terminal 300. For example, the terminal identification information may include a terminal identification value that uniquely identifies the user terminal 300, an application identification (ID) identifier that uniquely identifies a program 325 that is mounted on the user terminal 300 and communicates with the chip module 200 A key value exchanged between the program 325 of the user terminal 300 and the chip module 200, and an authentication value generated by using one or more of the values.

On the other hand, when the user purchases the signaling device 100 and connects the user terminal 300 owned by the user with the USB connector of the signaling device 100, the terminal registration part 224 registers the identification information in the identification information storage area Check whether the valid terminal identification information is registered. If valid terminal identification information is not registered in the identification information storage area, the terminal registration unit 224 tries to communicate with a specific program 325 installed in the cable-connected user terminal 300. If the specific program 325 communicating with the chip module 200 is installed in the user terminal 300, the terminal registration unit 224 communicates with the program 325 of the user terminal 300, Identifies the terminal identification information capable of uniquely identifying the terminal 300, and stores the identified terminal identification information in the identification information storage area.

When valid terminal identification information of the user terminal 300 is registered in the identification information storage area through the terminal registration unit 224, the terminal authentication unit 228 uses the terminal identification information registered in the identification information storage area The communication processing unit 240 can identify and authenticate the user terminal 300 connecting the bi-directional short-range wireless communication or the bidirectional USB data communication with the authenticated user terminal 300, It can handle wireless communication and bi-directional USB data communication.

On the other hand, when the bidirectional data communication between the user terminal 300 and the bidirectional data communication is established, the PIN registering unit 232 checks whether valid PIN authentication information is registered in the PIN storage area. If valid PIN authentication information is not registered in the PIN storage area, the PIN registration unit 232 registers the program 325 of the user terminal 300 connected with at least one bi-directional data communication among the bidirectional short-range wireless communication and the bidirectional USB data communication ) And store the PIN authentication information in the PIN storage area.

When valid PIN authentication information is registered in the PIN storage area, the PIN authentication unit 236 transmits the program 325 of the user terminal 300, which is connected to at least one bi-directional data communication among the bi- And the PIN authentication process of authenticating the user through the PIN authentication information. The PIN authenticating unit 236 may add or update the user terminal 300 or change important settings of the chip module 200 or initialize the settings of the chip module 200. [ PIN authentication procedure can be performed.

Referring to FIG. 2, the chip module 200 identifies the chip module 200 to the user terminal 300 connected to the bidirectional data communication when the at least one bidirectional data communication connection is established with the user terminal 300 And a module authentication processing unit 244 for providing chip module identification information to be authenticated.

The module authentication processing unit 244 stores chip module identification information for uniquely identifying and authenticating the chip module 200 in a designated storage area of the memory unit 208. The chip module identification information may include a unique module ID assigned at the time of manufacturing the chip module 200. The module authentication processing unit 244 registers the chip module identification information for authenticating the chip module 200 from the authenticated user terminal 300 through the PIN authentication unit 236, Or the chip module identification information including the key value obtained by performing the designated key exchange procedure with the program 325 of the user terminal 300 in the designated storage area of the memory unit 208 208 in the designated storage area. For example, the chip module identification information includes a module ID assigned to the chip module 200, a key value exchanged with the terminal 300, and an authentication value generated using at least one of the module ID and the key value can do.

When the bidirectional data communication between the user terminal 300 and the bidirectional data communication is established, the module authentication processing unit 244 identifies the chip module identification information and provides the chip module identification information to the user terminal 300 Thereby allowing the program 325 of the user terminal 300 to uniquely identify and authenticate the chip module 200.

When the module authentication processing unit 244 is provided in the chip module 200, the user terminal 300 (or the program 325 of the user terminal 300) connected with the bidirectional data communication through the terminal authentication unit 228 And the program 325 of the user terminal 300 authenticates the chip module 200 embedded in the signal device 100 through the chip module identification information by performing bidirectional mutual authentication In this case, the communication processing unit 240 can transmit / receive various information or data to / from the program 325 of the bidirectional mutually authenticated user terminal 300.

2, according to a first embodiment of the present invention, the chip module 200 includes an information storage unit 248 for storing unique information to be broadcasted through an asynchronous radio signal, an asynchronous And a signal transmitting unit 264 for controlling the radio signal to be broadcasted.

The information storage unit 248 may store unique information to be broadcasted through the asynchronous radio signal in the basic setting memory area at the time of manufacturing the chip module 200. Alternatively, the information storage unit 248 may receive unique information through at least one bi-directional data communication among bi-directional short-range wireless communication and bi-directional USB data communication, and store the unique information in the basic setting memory area.

The signal transmitting unit 264 confirms the unique information stored in the basic setting memory area of the memory unit 208 and transmits the basic setting asynchronous radio signal including the unique information of the basic setting memory area through the RF processor 212. [ And controls the signal to be broadcast. Preferably, the signal transmitting unit 264 may control to broadcast the asynchronous radio signal more than the designated number of times (or periodically).

2, according to a second embodiment of the present invention, the chip module 200 includes a code generation unit 260 for dynamically generating a one-time code to be broadcasted through an asynchronous radio signal, A seed storage unit (252) for storing one or more fixed seed values for generating the one-time code, and a seed storage unit (252) for generating the one-time seed And a seed determiner 256 for determining at least one dynamic seed value.

The seed storage unit 252 may store one or more fixed seed values for generating a one-time use code in the basic setting memory area at the time of manufacturing the chip module 200. Alternatively, the seed storage unit 252 may receive one or more fixed seed values through at least one bi-directional data communication among bi-directional short-range wireless communication and bi-directional USB data communication, and store the seed data in the basic setting memory area.

The seed determining unit 256 identifies at least one dynamic seed value (e.g., a time value, a random number, or the like) at the time of generating the disposable code. The seed determining unit 256 may receive the dynamic seed value through at least one bi-directional data communication among bi-directional short-range wireless communication and bi-directional USB data communication according to an embodiment.

The code generation unit 260 dynamically generates a one-time code for broadcasting through an asynchronous radio signal using a designated code generation algorithm. According to the method of the present invention, the code generation unit 260 generates at least one fixed seed value stored in the basic setting memory area of the memory unit 208 and at least one dynamic seed value determined through the seed determination unit 256 Values can be assigned to a specified code generation algorithm to dynamically generate one-off codes to broadcast over an asynchronous radio signal.

The signal transmitting unit 264 checks the one-time use code dynamically generated by the code generating unit 260 and controls the RF processing unit 212 to broadcast a basic asynchronous radio signal including the one-time code . Preferably, the signal transmitting unit 264 may control to broadcast the asynchronous radio signal more than the designated number of times (or periodically).

2, according to a third embodiment of the present invention, the chip module 200 includes an information storage unit 248 for storing unique information to be broadcasted through an asynchronous radio signal, And a signal transmitting unit (264) for controlling an asynchronous radio signal including the unique information and the disposable code to be broadcast, and a signal generating unit (264) for generating a disposable code And a seed determining unit 256 for determining at least one dynamic seed value for generating the one-time code.

The code generation unit 260 dynamically generates a one-time code to broadcast through the asynchronous radio signal using a designated code generation algorithm, and preferably generates one or more fixed seed values stored in the default setting memory area of the memory unit 208 And at least one dynamic seed value determined through the seed determiner 256 into the designated code generation algorithm to dynamically generate a disposable code to broadcast through the asynchronous radio signal.

The signal transmitting unit 264 confirms the unique information stored in the basic setting memory area of the memory unit 208 and confirms the one-time code dynamically generated by the code generating unit 260. The RF processing unit 212 And transmits the basic asynchronous radio signal including the unique information and the disposable code. Preferably, the signal transmitting unit 264 may control to broadcast the asynchronous radio signal more than the designated number of times (or periodically).

Referring to FIG. 2, the chip module 200 includes a power supply confirmation unit 268 for confirming a state in which vehicle power is being supplied from a vehicle, a vehicle power source And a mode setting unit (272) for setting or confirming a charging power source mode that is operated by using the charging power source charged in the power charging unit (130) when the vehicle power supply is not confirmed, And a signal controller 276 for amplifying the asynchronous radio signal broadcasted through the RF processor 212 when the power supply is confirmed and controlling the signal output of the asynchronous radio signal so that the asynchronous radio signal reaches the specified range outside the vehicle .

The power source confirmation unit 268 can confirm whether the vehicle power is supplied from the vehicle to the power supply unit 115 through a predetermined sensor (e.g., a current sensor, a voltage sensor, etc.). Alternatively, the power source verifying unit 268 can check whether the vehicle power is being converted through the power converting unit 120 through a predetermined sensor (not shown). Or the power supply confirmation unit 268 determines whether the power of the signal device 100 is grounded and checks whether the power of the vehicle is being supplied (for example, when the vehicle power is supplied, the ground of the power supply is connected to the vehicle body ) Grounded). Alternatively, the power source verifying unit 268 can determine whether the signal device 100 is receiving power from the vehicle through a predetermined sensor (for example, a pressure sensor, not shown) have. Preferably, the power source verifying unit 268 can determine whether the power of the vehicle is being supplied by combining at least one or more of the above embodiments.

When it is determined that the vehicle power is being supplied through the power source verifying unit 268, the mode setting unit 272 sets the operation mode of the chip module 200 to the operation mode using the vehicle power supplied from the vehicle Or the operation mode of the chip module 200 can be confirmed in the vehicle power mode.

If it is not confirmed that the power of the vehicle is being supplied through the power verifying unit 268, the mode setting unit 272 sets the operation mode of the chip module 200 to the power charging unit 130 Or the operation mode of the chip module 200 may be confirmed in the charging power mode.

According to the embodiment of the present invention, the mode setting unit 272 may set the operation mode of the chip module 200 to the supply state of the vehicle power through the separate operation unit provided in the signal device 100 The operation mode of the chip module 200 built in the signal device 100 can be set or confirmed.

When the operation mode of the chip module 200 is set or confirmed as the vehicle power mode, the signal controller 276 amplifies the asynchronous radio signal broadcasted through the RF processor 212 (for example, Amplified, or amplified to a maximum output) to control the signal output of the asynchronous radio signal so that the asynchronous radio signal reaches the specified range outside the vehicle (for example, 30 meters outside the vehicle). Generally, the signal device 100 is provided in a bottom part between a driver's seat and an assistant seat, or in a lower part of a steering wheel. This position is not only very strong electromagnetic interference of various electronic devices in the vehicle, The radio frequency signal transmitted through the antenna unit 216 of the chip module 200 by various blocking films attached to the windshield of the vehicle has difficulty in reaching the specified range outside the vehicle omnidirectionally. Of course, if the chip module 200 of the signal device 100 is positioned near the windshield of a vehicle to which no separate barrier film is attached, it is relatively easy to transmit the RF signal to reach the specified range outside the vehicle However, the position where the signal device 100 is provided may be a chip module (not shown) built in the signal device 100 for electromagnetic wave interference of various electronic devices in the vehicle, a metal material of a vehicle frame or a vehicle body, It is difficult to completely pass the radio frequency signal of the radio frequency signal 200 to a specified range outside the vehicle. When the signal device 100 receives power from the vehicle, the signal controller 276 outputs an asynchronous radio signal broadcasted through the RF processor 212 to the signal controller 276 in advance within a range available through the supplied vehicle power source. The asynchronous radio signal broadcasted by the chip module 200 may be transmitted to the electronic device through the communication line (not shown) of the various electronic devices in the vehicle by amplifying the digital signal by the calculated output (or at least the amplified output from the output of the low power mode) Or the metal material or the barrier film and can reach the specified range outside the vehicle.

Meanwhile, when the operation mode of the chip module 200 is set or confirmed as the charging power mode, the signal controller 276 controls to broadcast the asynchronous radio signal broadcasted through the RF processor 212 to the low power mode can do. The signal controller 276 may control the broadcasting of the asynchronous radio signal broadcasted through the RF processor 212 to an output of the BLE mode.

Referring to FIG. 2, the chip module 200 receives a user-defined asynchronous radio signal (hereinafter, referred to as an application-defined asynchronous radio signal) through a chip module 200 from a user terminal 300 connected with bidirectional data communication among bidirectional short- And a transmission control unit 284 for controlling to broadcast a usage-defined asynchronous radio signal corresponding to the setting information.

When the communication unit 240 is connected to the user terminal 300 by authenticating the user terminal 300 through at least one bi-directional data communication among the bi-directional short-range wireless communication and the bidirectional USB data communication, the communication processing unit 240 transmits the bi- Defined asynchronous radio signal through the chip module 200. The configuration information for controlling the use of the asynchronous radio signal is transmitted to the chip module 200. [ Preferably, the configuration information includes unique information to be included in the usage definition asynchronous radio signal, a seed value (e.g., one or more fixed seed values and / or at least one dynamic seed value) for generating a one- , A one-off code generated for inclusion in a use-defined asynchronous radio signal, and a protocol structure of a use-defined asynchronous radio signal for broadcasting an asynchronous radio signal for a specified purpose.

Referring to FIG. 2 according to the first embodiment of the present invention, the chip module 200 receives usage-defined asynchronous data from the user terminal 300 through at least one bi-directional data communication among bi- A communication processor 240 for receiving setting information including unique information to be broadcasted through a radio signal, an information storage 248 for storing unique information received for the use-defined asynchronous radio signal, And a signal transmitting unit 264 for controlling the use-defined asynchronous radio signal to be broadcasted.

The communication processing unit 240 communicates with the user terminal 300 through at least one bi-directional data communication among bi-directional short-range wireless communication and bi-directional USB data communication, And receives setting information including information. According to the embodiment of the present invention, the unique information received through the communication processing unit 240 may be a fixed value for defining a usage purpose, or may be a value that is defined by the user terminal 300 (or a designated server 370) And may include the generated one-time code.

The information storage unit 248 stores the unique information included in the setting information received from the user terminal 300 through the communication processing unit 240 in the usage definition memory area of the memory unit 208. [

The transmission control unit 284 may be configured to broadcast a default asynchronous radio signal based on the information stored in the basic setting memory area or to broadcast a usage definition asynchronous radio signal including unique information stored in the usage definition memory area Defined asynchronous radio signal through the signal transmitting unit 264 when it is determined to broadcast the use-defined asynchronous radio signal.

When it is determined to broadcast the use-defined asynchronous radio signal through the transmission control unit 284, the signal transmission unit 264 confirms the unique information stored in the usage definition memory area of the memory unit 208, Defined asynchronous radio signal including the unique information through the antenna 212 to broadcast. Preferably, the signal transmitting unit 264 may control the asynchronous radio signal to be transmitted more than the designated number of times (or periodically).

2 according to a second embodiment of the present invention, the chip module 200 receives a user-defined asynchronous communication request from the user terminal 300 through at least one bi-directional data communication among bidirectional short-range wireless communication and bidirectional USB data communication A communication processing unit (240) for receiving setting information including at least one seed value for dynamically generating a one-time code to be broadcasted through a radio signal; code generation means for generating a code for dynamically generating a one- And a signal transmission unit (264) for controlling a use-defined asynchronous radio signal including the generated one-time use code to broadcast the seed value received for the use-defined asynchronous radio signal, A storage unit 252, and a seed determining unit 256 for determining a seed value for generating the disposable code.

The communication processing unit 240 communicates with the user terminal 300 through at least one bi-directional data communication among bi-directional short-range wireless communication and bi-directional USB data communication, And receives setting information including a value. For example, the communication processing unit 240 may receive a fixed seed value for generating the one-time use code, and / or a dynamic seed value for generating the one-time use code.

The seed storage unit 252 stores one or more seed values included in the setting information received from the user terminal 300 through the communication processing unit 240 in the usage definition memory area of the memory unit 208. [ The seed value included in the setting information may include a fixed seed value for dynamically generating the one-time use code, and may include a dynamic seed value determined by the user terminal 300 to generate the one- .

The transmission control unit 284 may be configured to broadcast a basic asynchronous radio signal based on the information stored in the basic setting memory area or use definition including a disposable code generated using the seed value stored in the usage definition memory area Defined asynchronous radio signal through the signal transmitting unit 264 when it is determined to broadcast the asynchronous radio signal.

The seed determining unit 256 determines that the seed value (e.g., the fixed seed value and / or the dynamic seed value) stored in the usage definition memory area is to be broadcasted through the transmission control unit 284, And / or determines a separate dynamic seed value for generating a one-off code. The code generation unit 260 dynamically generates a one-time code for broadcasting through the use-defined asynchronous radio signal using a designated code generation algorithm. According to the method of the present invention, the code generation unit 260 substitutes one or more seed values identified from the usage definition memory area of the memory unit 208 and / or a separately determined dynamic seed value into a designated code generation algorithm It is possible to dynamically generate a disposable code to be broadcast through the usage definition asynchronous radio signal.

The signal transmitter 264 identifies the generated one-time code through the code generator 260, and controls the RF processor 212 to broadcast a use-defined asynchronous radio signal including the disposable code . Preferably, the signal transmitting unit 264 may control to broadcast the asynchronous radio signal more than the designated number of times (or periodically).

2, according to a third embodiment of the present invention, the chip module 200 receives usage definition asynchronous data from the user terminal 300 through at least one bidirectional data communication among bidirectional short-range wireless communication and bidirectional USB data communication A communication processing unit (240) for receiving configuration information including at least one seed value for dynamically generating a one-time code to broadcast through the use-defined asynchronous radio signal including unique information to be broadcast through a radio signal, An information storage unit 248 for storing unique information to be broadcasted through an asynchronous radio signal, a code generating unit 260 for dynamically generating a disposable code to be broadcast through the use definition asynchronous radio signal, And a signal transmission unit (264) for controlling to broadcast a usage definition asynchronous radio signal including the usage definition asynchronous radio signal The seed and the storage unit 252 to store the received seed value for at least one of the seed determining unit 256 for determining a seed value for generating the one-time codes further provided.

The communication processing unit 240 communicates with the user terminal 300 through at least one bi-directional data communication among bi-directional short-range wireless communication and bi-directional USB data communication, And one or more seed values for dynamically generating a one-off code to broadcast through the use-defined asynchronous radio signal.

The information storage unit 248 stores the unique information included in the setting information received from the user terminal 300 through the communication processing unit 240 in the usage definition memory area of the memory unit 208. [

The seed storage unit 252 stores one or more seed values included in the setting information received from the user terminal 300 through the communication processing unit 240 in the usage definition memory area of the memory unit 208. [ The seed value included in the setting information may include a fixed seed value for dynamically generating the one-time use code, and may include a dynamic seed value determined by the user terminal 300 to generate the one- .

The transmission control unit 284 may be configured to broadcast the basic asynchronous radio signal based on the information stored in the basic setting memory area or to transmit the seed value stored in the usage definition memory area including the unique information stored in the usage definition memory area Defined asynchronous radio signal including the one-time use code generated by using the use-defined asynchronous radio signal, and if the use-defined asynchronous radio signal is determined to be broadcast, transmits the use-defined asynchronous radio signal through the signal transmitting unit 264 To be broadcast.

The seed determining unit 256 determines that the seed value (e.g., the fixed seed value and / or the dynamic seed value) stored in the usage definition memory area is to be broadcasted through the transmission control unit 284, And / or determines a separate dynamic seed value for generating a one-off code. The code generation unit 260 dynamically generates a one-time code for broadcasting through the use-defined asynchronous radio signal using a designated code generation algorithm. According to the method of the present invention, the code generation unit 260 substitutes one or more seed values identified from the usage definition memory area of the memory unit 208 and / or a separately determined dynamic seed value into a designated code generation algorithm It is possible to dynamically generate a disposable code to be broadcast through the usage definition asynchronous radio signal.

The signal transmitting unit 264 confirms the unique information stored in the use definition memory area of the memory unit 208 and confirms the one-time code generated dynamically through the code generating unit 260. The RF processing unit 212 Defined asynchronous radio signal including the unique information and the disposable code. Preferably, the signal transmitting unit 264 may control to broadcast the asynchronous radio signal more than the designated number of times (or periodically).

According to the first usage definition signal embodiment of the present invention, the transmission control unit 284 may define a usage according to a control command of the user terminal 300 to which at least one of bi-directional short-range wireless communication and bidirectional USB data communication is connected You can decide whether to broadcast an asynchronous radio signal or a default asynchronous radio signal.

According to the second usage definition signal embodiment of the present invention, the transmission control unit 284 controls the USB connector unit 125 and the user terminal 300 in a state where valid setting information is stored in the usage definition memory area according to a designated scenario, You can decide whether to broadcast an application-defined asynchronous radio signal or a default asynchronous radio signal based on whether a USB connection is connected or disconnected. For example, when the asynchronous radio signal broadcasted through the setting information stored in the usage definition memory area is an asynchronous radio signal defined as a use for a parking position confirmation service of a parking lot, the transmission control unit 284 controls the USB connector Defined asynchronous radio signal for confirming the parking position by considering that the user is operating the vehicle when a USB connection is established between the user 125 and the user terminal 300, If the USB connection between the USB connector 125 and the user terminal 300 is disconnected while broadcasting the signal, the user assumes that the user has finished parking the vehicle and has come down from the vehicle, and controls the use of the defined asynchronous radio signal for confirming the parking position Or may be deactivated.

According to the third usage definition signal embodiment of the present invention, the transmission control unit 284 can perform bidirectional short-range wireless communication with the user terminal 300 in a state where valid setting information is stored in the usage definition memory area according to a specified scenario Based on whether or not it is impossible to broadcast an asynchronous radio signal or a default asynchronous radio signal. For example, if the asynchronous radio signal broadcasted through the setting information stored in the usage definition memory area is an asynchronous radio signal defined as a use for parking parking payment service of a designated parking lot, the transmission control unit 284 controls the transmission / It is assumed that the user is operating the vehicle when bidirectional short-range wireless communication with the mobile terminal 300 is possible, so that the asynchronous radio signal can be controlled to be broadcast.

According to the fourth usage definition signal embodiment of the present invention, the transmission control unit 284 controls to broadcast the usage definition asynchronous radio signal while storing valid setting information in the usage definition memory area according to a specified scenario, Defined asynchronous radio signal is not broadcasted or is deactivated when a specific signal is received over time or from at least one of bi-directional short-range wireless communication or bi-directional USB data communication from the user terminal 300 . For example, when the asynchronous radio signal broadcasted through the setting information stored in the usage definition memory area is an asynchronous radio signal defined as a service for a parking fee settlement service of a parking lot, the transmission control unit 284 controls the usage definition The controller 300 controls the broadcasting of the usage-defined asynchronous radio signal for the payment of the parking fee while the setting information is stored in the memory area and the payment completion signal for the parking fee is received from the user terminal 300 through bidirectional short- Defined asynchronous radio signal for paying the parking fee.

According to the fifth use definition signal embodiment of the present invention, the transmission control unit 284 may be configured to partially or at least mix at least two of the first to fourth use definition signal embodiments to broadcast the use definition asynchronous radio signal, You can decide whether to broadcast the default asynchronous radio signal.

According to the method of the present invention, the communication processing unit 240 determines whether a basic asynchronous radio signal is being broadcasted through the signal transmission unit 264, or whether a usage-defined asynchronous radio signal is transmitted under control of the transmission control unit 284 And transmits signaling information for identifying a state of whether the asynchronous radio signal of the basic setting asynchronous radio signal and the asynchronous radio signal of the use definition is configured to transmit the bidirectional short range wireless communication or the bidirectional USB data communication To the user terminal 300 through at least one bi-directional data communication, so that the user terminal 300 can identify the asynchronous radio signal being broadcast through the chip module 200. [

2, when the chip module 200 operates through a vehicle power source and bidirectional short-range wireless communication between the chip module 200 and the user terminal 300 is connected, And a USB control unit 280 for deactivating bidirectional USB data communication of the communication unit 204 and activating bidirectional USB data communication of the USB communication unit 204 when not in operation, Way USB data communication with the user terminal 300 connected to the USB connector unit 125 through the USB communication unit 204 when bi-directional USB data communication of the USB communication unit 204 is activated.

The operation mode of the chip module 200 is set or confirmed as the vehicle power mode by operating the chip module 200 through the vehicle power source and the short range wireless communication function of the user terminal 300 is activated, Directional WiFi communication between the user terminal 300 and the user terminal 300 is enabled, the USB control unit 280 can control the bi-directional USB data communication function through the USB communication unit 204 to be inactivated. That is, if a user connects a certain external device (for example, a navigation device or a user terminal 300) to the USB connector 125 of the signaling device 100 after connecting the vehicle power source to the signaling device 100 , Which is likely to be the intent of the user to supply vehicle power to the cabled external device using the signaling device 100 as a power supply. If bi-directional USB data communication is activated each time the external device is connected to the USB connector 125, the user does not intend to perform bi-directional USB data communication between the external device and the chip module 200. However, And it may inconvenience that it should be released. The USB controller 280 controls the operation of the chip module 200 through the vehicle power source and the bi-directional short-range wireless communication between the chip module 200 and the user terminal 300 is connected, It is possible to control the signaling device 100 to operate as a power supply device including the USB connector 125 by disabling bidirectional USB data communication of the USB communication unit 204. [

If the vehicle power supply is not confirmed, or if the chip module 200 operates through the charging power source or bidirectional short-range wireless communication with the user terminal 300 is not confirmed, the USB controller 280 The bidirectional USB data communication function through the USB communication unit 204 can be controlled to be activated. That is, when the user does not confirm the power supply of the vehicle, or when the chip module 200 operates through the charging power supply or when bidirectional short-range wireless communication with the user terminal 300 is not confirmed, It is assumed that the user intends to perform bidirectional USB data communication with the chip module 200 of the signaling device 100 and the USB communication unit 204 is connected to the USB connector 125 of the signaling device 100. [ Way USB data communication function can be activated.

3 is a functional block diagram of a user terminal 300 and a program 325 according to an embodiment of the present invention.

3, the user terminal 300 includes a control unit 302, a memory unit 320, a screen output unit 304, a user input unit 306, a sound processing unit 308, a cable communication unit 310, A short range communication unit 312, a short range wireless communication unit 314, a wireless network communication unit 316, a USIM reader unit 318, and a USIM, and has a battery for power supply.

The control unit 302 is a general term for controlling the operation of the user terminal 300 and includes at least one processor and an execution memory. ). According to the present invention, the control unit 302 loads at least one program code provided in the user terminal 300 through the processor and loads the program code into the execution memory, and outputs the result to at least one constituent unit And controls the operation of the user terminal 300. Hereinafter, the configuration of the program 325 of the present invention, which is implemented in the form of program code for convenience, will be described in the control unit 302. FIG.

The memory unit 320 is a general term of a nonvolatile memory corresponding to a storage resource of the user terminal 300 and includes at least one program code executed through the control unit 302 and at least one data Save and keep the set. The memory unit 320 basically includes a system program code and a system data set corresponding to an operating system of the user terminal 300, a communication program code and a communication data set for processing a wireless communication connection of the user terminal 300, The program code and the data set corresponding to the program 325 of the present invention are also stored in the memory unit 320. [

The screen output unit 304 includes a screen output unit (e.g., an LCD (Liquid Crystal Display) or the like) and a driving module for driving the screen output unit 304. The screen output unit 304 is connected to the control unit 302, And outputs an operation result corresponding to the output to the screen output device.

The user input unit 306 includes at least one user input device (e.g., a button, a keypad, a touch pad, a touch screen coupled to the screen output unit 304), and a drive module for driving the touch screen. And inputs a command for instructing various operations of the control unit 302 or data necessary for the operation of the control unit 302. [

The sound processing unit 308 includes a speaker, a microphone, and a drive module for driving the sound processor 308. The sound processor 308 decodes sound data corresponding to a sound output from various calculation results of the controller 302 and outputs the sound data through the speaker Or a sound signal input through the microphone, and transmits the encoded sound signal to the controller 302. [

The cable communication unit 310 receives power using a cable or provides bi-directional USB data communication. The power supplied through the cable is charged in the battery. The cable communication unit 310 determines whether bi-directional USB data communication is possible when the wired cable is connected, and bi-directional USB data communication is performed using a wired cable when USB communication is possible.

The short-range communication unit 312 transmits and receives a radio frequency signal of a specified standard at a short distance of about 10m (within a maximum of about 100m) according to a specified standard. Preferably, the short-range communication unit 312 can transmit and receive a Wi-Fi-based radio frequency signal in a short distance of about 10 m or less (up to about 100 m) in accordance with a Wi-Fi communication standard. However, the short-range communication unit 312 is not limited to transmitting and receiving a Wi-Fi-based radio frequency signal according to the Wi-Fi communication standard, and may transmit and receive a radio frequency signal according to another standard. Meanwhile, when the local area network communication unit 314 connects to the data communication network based on the Wi-Fi communication standard, the local area communication unit 312 and the local area network communication unit 314 may be integrated or the same module, x will be described with reference to the short-range communication unit 312 and the short-range network communication unit 414, respectively. The short-range communication unit 312 may process bidirectional short-range wireless communication with the chip module 200 embedded in the OBD apparatus 100. [

The wireless network communication unit 316 and the short-range network communication unit 314 are collectively referred to as communication resources for connecting the user terminal 300 to a designated communication network. The wireless network communication unit 316 collectively refers to a communication resource for connecting the user terminal 300 to a wireless communication network via a base station, and includes an antenna, an RF module, a baseband module, a signal processing unit And transmits the calculation result corresponding to the wireless communication among the various calculation results of the controller 302 to the controller 302 through the wireless communication network or receives the data through the wireless communication network To the control unit 302, and performs the connection, registration, communication, and handoff procedures of the wireless communication. According to the present invention, the wireless network communication unit 316 can connect the user terminal 300 to a call network including a call channel and a data channel via an exchange, and in some cases, To a data network that provides wireless network data communication (e.g., the Internet).

The short-range network communication unit 314 collectively refers to a communication resource for connecting a communication session using a radio frequency signal within a predetermined distance (for example, 10 m) as a communication medium and connecting the user terminal 300 to the communication network based on the communication session, Preferably, the user terminal 300 may be connected to the communication network through at least one of Wi-Fi communication, public wireless communication, and UWB. According to an embodiment of the present invention, the local area network communication unit 314 may be integrated with or separated from the wireless network communication unit 316. According to the present invention, the short-range network communication unit 314 connects the user terminal 300 to a data network providing packet-based short-range wireless data communication through the wireless AP.

The USIM reader 318 is a general term for a configuration in which at least one data set is exchanged with a universal subscriber identity module that is mounted or detached from the user terminal 300 based on the ISO / IEC 7816 standard , The data set is exchanged in a half-duplex communication manner through an APDU (Application Protocol Data Unit).

The control unit 302 downloads a program 325 linked with the chip module 200 of the signaling device 100 and stores the downloaded data network in the memory unit 320, 325 are driven to perform operations according to the present invention.

Referring to FIG. 3, a program 325 of the user terminal 300 includes bidirectional USB data communication by cable connection to a USB connector 125 provided in the signaling device 100, Directional data communication with the chip module 200 built in the signaling device 100 through at least one of bidirectional short-range wireless communication using the short-range wireless communication function of the signaling device 100.

The communication connection unit 330 identifies the paired chip module 200 through the local communication unit 312 and connects the bi-directional local area wireless communication with the paired chip module 200 through the local communication unit 312 .

When the cable communication unit 310 and the USB connector unit 125 of the signal device 100 are connected through a cable and the bi-directional USB data communication function of the chip module 200 is activated, the communication connection unit 330 Can detect the chip module 200 embedded in the signaling device 100 through bidirectional USB data communication using the cable and can connect bidirectional USB data communication with the chip module 200. [

According to the embodiment of the present invention, when the communication connection unit 330 is paired with the chip module 200 of the signaling device 100 through the short-range communication unit 312, And can selectively connect bi-directional USB data communication with the chip module 200 when the bi-directional short-range wireless communication is not possible.

Referring to FIG. 3, the program 325 of the user terminal 300 includes a procedure for registering PIN authentication information in the chip module 200 of the signaling device 100 and / And a PIN authentication procedure unit 335 for performing a PIN authentication procedure using the authentication information.

Directional data communication between the chip module 200 of the signaling device 100 and the bi-directional short-range wireless communication or bi-directional USB data communication is connected through the communication connection unit 330, The PIN authentication procedure unit 335 may register the PIN authentication information in the chip module 200 connected to the bidirectional data communication.

Meanwhile, when the PIN authentication information is registered in the chip module 200 connected to the directional data communication, the PIN authentication procedure unit 335 adds / updates the user terminal 300 according to the designated scenario, Or may perform a PIN authentication procedure using the PIN authentication information of the chip module 200 by receiving the PIN information from the user when the setting of the chip module 200 is initialized.

3, the program 325 of the user terminal 300 registers the terminal identification information for the user terminal 300 (or the program 325) in the chip module 200 connected to the bidirectional data communication (Not shown) to the chip module 200 using the bidirectional data communication connection, and transmits the terminal identification information to the chip 300 connected to the bidirectional data communication 200 If the terminal identification information for the user terminal 300 is registered, the terminal identification information is provided to the chip module 200 through the bidirectional data communication and the user terminal 300 (or the program 325 ) Of the mobile terminal 300. The terminal authentication procedure unit 340 performs the procedure of authenticating the validity of the mobile terminal 300 (e.g.

When the valid terminal identification information for the user terminal 300 is not registered in the chip module 200 of the signaling device 100 connected to the bidirectional data communication through the communication connection unit 330 or as a result of the PIN authentication, When adding / updating terminal identification information to / from the chip module 200, the terminal authentication procedure unit 340 configures terminal identification information for uniquely identifying and authenticating the user terminal 300 (or the program 325) To the chip module 200 of the bidirectional data communication connected signaling device 100. The chip module 200 stores the terminal identification information in a designated identification information storage area.

When valid terminal identification information is registered in the chip module 200 of the bidirectional data communication connected signaling device 100 through the communication connection unit 330, the terminal authentication processing unit 340 transmits the bidirectional data communication signal to the bi- (Or program 325) with the chip module 200 of the mobile terminal 100 (e.g., the mobile terminal 100). The chip module 200 authenticates the validity of the provided terminal identification information by using the terminal identification information registered in the designated identification information storage area and replies with the result.

According to the embodiment of the present invention, when the validity of the terminal 300 (or the program 325) is authenticated through the terminal identification information in the chip module 200 of the signaling device 100, And the user terminal 300 through the bidirectional data communication.

Referring to FIG. 3, the program 325 of the user terminal 300 includes a chip module identification information of the chip module 200 embedded in the signaling device 100 in the memory unit 320 of the terminal 300 The controller 300 registers the chip module identification information of the chip module 200 in the memory unit 320 using the bidirectional data communication connection and notifies the memory unit 320 of the terminal 300 of the signal When the chip module identification information of the chip module 200 embedded in the device 100 is registered, the validity of the chip module 200 by receiving the chip module identification information of the chip module 200 through the bidirectional data communication And a module authentication procedure unit 345 for performing the authentication procedure.

If the chip module identification information for uniquely identifying and authenticating the chip module 200 of the signaling device 100 is not stored in the designated storage area of the terminal 300, the module authentication procedure module 345 reads the bi- The chip module identification information for the chip module 200 is received from the connected chip module 200 and stored in a designated storage area or a chip module identification for uniquely identifying and authenticating the chip module 200 connected to the bidirectional data communication Information is provided to the chip module 200 and stored in a designated storage area. Preferably, the chip module identification information can be encrypted and stored.

When the chip module identification information is stored in the designated storage area of the user terminal 300, the module authentication procedure unit 345 reads the chip module identification information from the chip module 200 of the bidirectional data communication- And validates the validity of the received chip module identification information using the chip module identification information stored in the designated storage area.

According to an embodiment of the present invention, when the module authentication procedure unit 345 authenticates the validity of the chip module 200 of the bidirectional data communication-connected signaling device 100 through the chip module identification information, Various data or data can be transmitted / received through bidirectional data communication between the mobile terminal 200 and the user terminal 300.

Referring to FIG. 3, the program 325 of the user terminal 300 controls to broadcast an asynchronous radio signal defined for a specific purpose through the chip module 200 of the bidirectional data communication-connected signaling device 100 And a communication procedure unit 355 for providing the setting information to the chip module 200 of the signaling device 100 through the bidirectional data communication. The communication procedure unit 355 may determine that the chip module 200 of the signaling device 100 has been authenticated when the authentication procedure performed through the terminal authentication procedure unit 340 and / or the module authentication procedure unit 345 is authenticated. And performs a procedure of transmitting and receiving various information or data.

The information generating unit 350 generates the information input by the user and the designated server 370 before, during, after, and after the communication connection with the chip module 200 of the signaling device 100 through the communication connection unit 330. [ ) To generate setting information for controlling to broadcast an asynchronous radio signal defined for a specific purpose through the chip module 200 of the signaling device 100. [

When the setting information for controlling the broadcasting of the asynchronous radio signal defined for a specific purpose is generated through the chip module 200 of the signaling device 100 through the information generating unit 350, The chip module 200 provides the setting information to the chip module 200 of the bidirectional data communication connected signaling device 100 and the chip module 200 controls to broadcast a usage definition asynchronous radio signal corresponding to the setting information.

Referring to FIG. 3, the program 325 of the user terminal 300 may transmit the setting information to the chip module 200 of the signaling device 100, A communication procedure section (355) for receiving signal transmission information for identifying a non-synchronous radio signal broadcast from any one of a basic setting asynchronous radio signal and a use definition asynchronous radio signal from the chip module (200) Defined asynchronous radio signal corresponding to the setting information is being broadcasted through an information output unit (200) for outputting information corresponding to the use-defined asynchronous radio signal during broadcast or interruption of the broadcast, (365).

According to the first signal discrimination embodiment of the present invention, when the setting information is provided to the chip module 200 of the signaling device 100, the communication procedure unit 355 may transmit the setting information to the chip module 200 of the signaling device 100, Receives signal transmission information for discriminating whether a basic asynchronous radio signal is being broadcasted through the chip module (200) or a use-defined asynchronous radio signal corresponding to the setting information is received from the signal determiner (200) 360 reads out the received signal transmission information and determines whether the use-defined asynchronous radio signal corresponding to the setting information is being broadcast or the basic asynchronous radio signal is being broadcast through the chip module 200.

If the basic setting asynchronous radio signal is being broadcast through the chip module 200 of the signal transmission apparatus 100 as a result of reading the signal transmission information, the information output unit 365 outputs information corresponding to the basic asynchronous radio signal broadcasting (Or broadcast interruption of the use-defined asynchronous radio signal). If the usage definition asynchronous radio signal corresponding to the setting information is being broadcast through the chip module 200 of the signal transmission apparatus 100, the information output unit 365 may correspond to the setting information And outputs information corresponding to the usage definition asynchronous radio signal broadcasting.

If the application-defined asynchronous radio signal is not transmitted through the chip module 200 after the setting information is provided to the chip module 200 of the signaling device 100, Definition information for broadcasting the asynchronous radio signal to the chip module 200 of the signaling device 100 through the bidirectional data communication.

According to the second signal discrimination embodiment of the present invention, when the setting information is provided to the chip module 200 of the signaling device 100, the signal discrimination unit 360 interlocks with the short range communication unit 312 The asynchronous radio signal can be transmitted without pairing and is also received by the short range communication unit 312 of the terminal 300. The short range communication unit 312 transmits the asynchronous radio signal through the chip module 200 of the signal device 100, ) Asynchronous radio signal, reads out the asynchronous radio signal transmitted through the chip module (200), and determines whether the usage definition asynchronous radio signal corresponding to the setting information is being broadcast through the chip module (200) It is possible to determine whether the radio signal is being broadcast.

If the asynchronous radio signal is being broadcast through the chip module 200 of the signal device 100 as a result of reading the asynchronous radio signal transmitted from the chip module 200, And outputs information corresponding to the information corresponding to the asynchronous radio signal broadcast (or broadcast interruption of the use-defined asynchronous radio signal). If a usage definition asynchronous radio signal corresponding to the setting information is being broadcast through the chip module 200 of the asynchronous radio signal reading out signal device 100 transmitted from the chip module 200, 365) outputs information corresponding to the usage definition asynchronous radio signal broadcasting corresponding to the setting information.

If the application-defined asynchronous radio signal is not transmitted through the chip module 200 after the setting information is provided to the chip module 200 of the signaling device 100, Definition information for broadcasting the asynchronous radio signal to the chip module 200 of the signaling device 100 through the bidirectional data communication.

According to the third signal discrimination embodiment of the present invention, bi-directional USB data communication is connected between the chip module 200 of the signaling device 100 and the user terminal 300, and the chip module 200 The signal determining unit 360 determines whether the cable connection is released or the cable communication unit 310 disconnects the cable from the USB connector 125 of the signaling device 100. [ The cable is detached and the cable connection is released.

According to an embodiment of the present invention, the chip module 200 of the signaling device 100 can automatically stop the broadcast of the application-defined asynchronous radio signal when the cable is disconnected. In this case, when the cable is disconnected, the signal determining unit 360 can determine that the use-defined asynchronous radio signal corresponding to the setting information is stopped through the chip module 200 of the signaling device 100 , The information output unit 365 can output information corresponding to the basic setting asynchronous radio signal broadcasting (or broadcast stop of the usage definition asynchronous radio signal).

Meanwhile, as a modified example of the third signal discrimination embodiment, the signal discrimination unit 360 can confirm whether bi-directional USB data communication between the chip module 200 and the user terminal 300 is possible. If the chip module 200 is set to automatically stop the broadcast of the application-defined asynchronous radio signal when the bidirectional USB data communication is not possible, the signal determination unit 360 determines whether the chip module 200 is connected to the user terminal 300, It is possible to determine that the broadcast of the use-defined asynchronous radio signal is interrupted through the chip module 200 when the bidirectional USB data communication is impossible, It is possible to output information corresponding to the information corresponding to the basic setting asynchronous radio signal broadcasting (or the broadcasting stop of the usage definition asynchronous radio signal).

Directional short-range wireless communication is connected between the chip module 200 and the user terminal 300 of the signaling device 100 and the chip module 200 is connected to the signal module 100 through the bidirectional short- 200, the signal determination unit 360 can confirm whether bidirectional short-range wireless communication with the chip module 200 is possible.

According to the embodiment of the present invention, the chip module 200 of the signaling device 100 can automatically stop the broadcast of the application-defined asynchronous radio signal when the bidirectional short-range wireless communication is not possible. In this case, when the bidirectional short-range wireless communication is not possible, the signal determining unit 360 determines that the use-defined asynchronous radio signal corresponding to the setting information is stopped through the chip module 200 of the signaling device 100 And the information output unit 365 may output information corresponding to the basic setting asynchronous radio signal broadcasting (or broadcasting stop of the usage definition asynchronous radio signal).

According to the fifth signal discrimination embodiment of the present invention, the signal discrimination unit 360 may combine two or more of the first to fourth signal discrimination embodiments, It is possible to determine whether the setting asynchronous radio signal is being broadcast (or the broadcast interruption of the use-defined asynchronous radio signal) or the use-defined asynchronous radio signal corresponding to the setting information is being broadcast, and thus the present invention is not limited thereto.

The communication procedure unit 355 may transmit the signal through the chip module 200 of the signaling device 100 in accordance with the user operation (or reception of information from the designated server 370) And stop the broadcast of the application-defined asynchronous radio signal to the chip module 200. The chip module 200 receives the interruption information and transmits the interruption information to the chip module 200, Definition You can interrupt the broadcast of asynchronous radio signals.

4 is a diagram illustrating a mode setting / checking process of the chip module 200 according to an embodiment of the present invention.

4 shows a process of automatically setting / switching the operation mode of the chip module 200 built in the signal device 100 to the vehicle power supply mode or the charging power supply mode according to the vehicle power supply or the charging power supply Those skilled in the art will be able to refer to and / or modify Figure 4 to illustrate various modes of operation of the chip module 200 It is to be understood that the invention may be practiced otherwise than as specifically described herein, but it is to be understood that the invention is not limited to the disclosed embodiments, .

Referring to FIG. 4, when operation power is supplied to the chip module 200 embedded in the signal device 100 (400), the chip module 200 determines whether power is supplied from the vehicle (405). If power is supplied from the vehicle, the chip module 200 sets (410) the operation mode to the vehicle power mode.

On the other hand, if the operation power is not supplied from the vehicle but the power charged in the power charging unit 130 is supplied, the chip module 200 sets or confirms the operation mode to the charging power mode (415).

5 is a diagram illustrating a process of registering terminal identification information and chip module identification information according to an embodiment of the present invention.

5 is a block diagram of a chip module 200 of a signaling device 100 when at least one bi-directional data communication between bidirectional short-range wireless communication and bidirectional USB data communication is connected between the chip module 200 and the user terminal 300. [ The terminal identification information for the user terminal 300 is registered in the identification information storage area of the terminal 200. It should be appreciated by those skilled in the art that the present invention can be implemented by referring to FIG. Alternatively, various embodiments of the terminal identification information registration procedure may be inferred (for example, some steps may be omitted or the procedure may be changed in order), but the present invention includes all of the above embodiments And the technical features thereof are not limited only by the method shown in FIG.

Referring to FIG. 5, the chip module 200 of the signaling device 100 performs a bidirectional USB data communication and a bi-directional short-range wireless communication while operating through a power source of the vehicle and a power source charged in the power source charging unit 130 (500), and the program (325) of the user terminal (300) is also connected to the user terminal (300) through one of bidirectional USB data communication and bidirectional local area wireless communication And confirms the communication connection with the chip module 200 of the signaling device 100 (500).

When bi-directional data communication is established between the chip module 200 and the user terminal 300, the chip module 200 checks whether valid terminal identification information is registered in the designated identification information storage area (505). If valid terminal identification information is not registered in the identification information storage area, the chip module 200 can request terminal identification information to the user terminal 300 through the bi-directional data communication.

According to another embodiment of the present invention, when the bi-directional data communication with the chip module 200 is connected to the program 325 of the user terminal 300, the program module 325 of the user terminal 300 Or program 325) is registered (515). If the program 325 is executed for the first time or there is no history of registering the terminal identification information in advance, the program 325 of the user terminal 300 determines that the valid terminal identification information is not registered in the chip module 200 Can be confirmed.

If it is determined that the terminal identification information is requested from the chip module 200 or that the valid terminal identification information is not registered in the chip module 200 in the program 325 of the user terminal 300, The program 325 of the user terminal 300 constructs 520 valid terminal identification information for the user terminal 300 (or program 325) and transmits the validated terminal identification information to the chip module 200 via the bidirectional data communication The chip module 200 receives the terminal identification information through the bidirectional data communication and stores the terminal identification information in the identification information storage area (step 525) 530).

According to another embodiment of the present invention, when valid terminal identification information is previously registered in the identification information storage area of the chip module 200 and terminal identification information of the identification information storage area is updated or added, After the PIN authentication process using the PIN authentication information registered in the PIN storage area of the chip module 200 through the user terminal 300 corresponding to valid terminal identification information previously registered in the identification information storage area of the chip module 200 The terminal identification information can be registered in the chip module 200.

Meanwhile, when the terminal identification information is registered in the chip module 200 or bidirectional data communication is connected to the chip module 200, the program 325 of the user terminal 300 is transmitted to the chip module 200 (535) whether the chip module identification information for the user terminal 300 is stored in the memory unit 320 of the user terminal 300. If the chip module identification information is not stored, the program 325 of the user terminal 300 can request and confirm the chip module identification information registered in the chip module 200 through the bidirectional data communication The chip module 200 may provide the chip module identification information registered in the bi-directional data communication to the user terminal 300 in response to the request of the user terminal 300 (540) . According to another embodiment of the present invention, the program 325 of the user terminal 300 determines predetermined chip module identification information to be set in the chip module 200, and transmits the chip module identification information to the chip module 200 (540), and the chip module 200 can receive and store the chip module identification information through the bidirectional data communication (540). The program 325 of the user terminal 300 stores the chip module identification information registered / set in the chip module 200 in the memory unit 320 (545).

6 is a diagram illustrating a process of authenticating the terminal 300 or authenticating the chip module 200 according to an embodiment of the present invention.

6 shows an example in which valid terminal identification information of the user terminal 300 is registered in the chip module 200 of the signaling device 100 through the process shown in FIG. The program 325 of the user terminal 300 and the chip module 200 perform mutual authentication using the respective identification information when valid chip module identification information for the module 200 is registered , It is possible to refer to and / or modify the configuration of FIG. 6 by various methods of authentication of the terminal 300 or the chip module 200 The present invention is not limited to the above-described embodiments, but the technical features may be limited only by the method shown in FIG. 6 It does.

6, when valid terminal identification information for the user terminal 300 (or the program 325) is registered in the chip module 200 of the signaling device 100, the program of the user terminal 300 The chip module 200 provides the terminal identification information for uniquely identifying and authenticating the terminal 300 (or the program 325) to the chip module 200 through the bidirectional data communication 600, The terminal identification information is received through bidirectional data communication from the program 325 of the user terminal 300 (605).

The chip module 200 authenticates the validity of the terminal identification information received from the terminal 300 using the terminal identification information registered in the identification information storage area (610). If the validity of the terminal identification information is not authenticated, the chip module 200 provides an authentication result including an authentication error to the program 325 of the user terminal 300 (615). Meanwhile, when the validity of the terminal identification information is authenticated, the chip module 200 provides an authentication result corresponding to the authentication success of the terminal identification information to the program 325 of the user terminal 300 (615). When the validity of the terminal identification information is authenticated, the chip module 200 may receive setting information for broadcasting a usage definition asynchronous radio signal from the program 325 of the authenticated user terminal 300. [

The program 325 of the user terminal 300 receives and reads the authentication result of the terminal identification information (620). If the validity of the terminal identification information is not authenticated, the program 325 of the user terminal 300 outputs an authentication error (625). Meanwhile, when the validity of the terminal identification information is authenticated, the program 325 of the user terminal 300 may provide the setting information for controlling the use of the asynchronous radio signal for use definition through the chip module 200 .

The program 325 of the user terminal 300 determines whether chip module identification information for the chip module 200 to which the bidirectional data communication is connected is stored in a designated storage area of the user terminal 300 in operation 630. If the chip module identification information for the chip module 200 is not stored, the program 325 of the user terminal 300 sets / registers the chip module identification information through the process shown in FIG. 5 Can be performed. Meanwhile, if the chip module identification information for the chip module 200 is stored in the designated storage area of the user terminal 300, the program 325 of the user terminal 300 may transmit the chip module identification information to the chip module 200 using bidirectional data communication. 200 to the chip module 200 in step 635 and the chip module 200 checks the chip module identification information in step 640 and provides the chip module identification information to the program 325 of the user terminal 300 in step 645.

The program 325 of the user terminal 300 authenticates the validity of the chip module identification information received from the chip module 200 using the chip module identification information stored in the designated storage area. If the validity of the chip module identification information is not authenticated, the program 325 of the user terminal 300 outputs an authentication error (625).

Meanwhile, if the validity of the chip module identification information is authenticated, the program 325 of the user terminal 300 provides an authentication result of the chip module identification information to the chip module 200 (655). The chip module 200 receives the authentication result of the chip module identification information from the program 325 of the user terminal 300 in step 660 and then transmits the application definition asynchronous operation from the program 325 of the user terminal 300 And can receive setting information for broadcasting a radio signal.

7 is a diagram illustrating an asynchronous radio signal broadcasting process of the chip module 200 according to the first embodiment of the present invention.

In more detail, FIG. 7 selectively broadcasts a basic asynchronous radio signal including unique information of the chip module 200 according to the power supply state, and transmits the program (FIG. 6) of the authenticated user terminal 300 Defined asynchronous radio signal corresponding to the setting information when the setting information is received from the base station and the base station, (For example, omitting some steps or changing the sequence) of the asynchronous radio signal broadcasting process of the chip module 200. However, the present invention can be applied to the case All the methods of implementation are included, and the technical characteristics thereof are not limited only by the method shown in FIG.

Referring to FIG. 7, when operation power is supplied to the chip module 200 incorporated in the signaling device 100, the chip module 200 checks the unique information stored in the basic setting memory area 700, And generates a default asynchronous radio signal including information (705).

If the operation mode of the chip module 200 is the vehicle power mode in which the operation is performed by receiving power from the vehicle, the chip module 200 amplifies the basic asynchronous radio signal using the power supplied from the vehicle, Amplified to the pre-calculated output, or amplified to the maximum output available) and broadcast 710.

On the other hand, if the operation mode of the chip module 200 is the charge power mode in which the power charged in the power charging unit 130 is supplied, the chip module 200 broadcasts the basic set asynchronous radio signal in the low power mode (715 ).

The chip module 200 checks 720 whether the setting information generated through the process shown in FIG. 10 is received from the program 325 of the authenticated user terminal 300 through the process shown in FIG. If the setting information is not received, the chip module 200 repeats the broadcasting of the basic asynchronous radio signal more than or a specified number of times.

Meanwhile, when the setting information is received from the program 325 of the authenticated user terminal 300, the chip module 200 stores the value / information included in the setting information in the designated usage definition memory area 725, Defined asynchronous radio signal including the unique information of the setting information and / or using the dynamically generated one-time code using the value included in the setting information (730).

If the operation mode of the chip module 200 is a vehicle power mode in which power is supplied from the vehicle, the chip module 200 amplifies the use-defined asynchronous radio signal using the power supplied from the vehicle, Amplified to a pre-calculated output, or amplified to the maximum output available) and broadcast 735.

On the other hand, if the operation mode of the chip module 200 is the charge power mode in which the power charged in the power charging unit 130 is supplied, the chip module 200 broadcasts the application defined asynchronous radio signal in the low power mode (740 ).

The chip module 200 determines whether the use-defined asynchronous radio signal is to be broadcasted while broadcasting the use-defined asynchronous radio signal (745). If the broadcast interruption of the use-defined asynchronous radio signal is not determined, the chip module 200 repeats the process of broadcasting the use-defined asynchronous radio signal a predetermined number of times or periodically.

Meanwhile, when the broadcast interruption of the use-defined asynchronous radio signal is determined, the chip module 200 performs a process of broadcasting the basic asynchronous radio signal.

8 is a diagram illustrating an asynchronous radio signal broadcasting process of the chip module 200 according to the second embodiment of the present invention.

In more detail, FIG. 8 selectively broadcasts a basic asynchronous radio signal including a disposable code generated through the chip module 200 according to a power supply state, Defined asynchronous radio signal corresponding to the setting information when the setting information is received from the program 325 of FIG. 8A. As a person skilled in the art, (E.g., omitting some steps or changing the order) of the asynchronous radio signal broadcasting process of the chip module 200. The present invention is not limited to the above embodiments, And all of the above-mentioned embodiments can be deduced. The technical features of the present invention are not limited only by the method shown in FIG.

Referring to FIG. 8, when operating power is supplied to the chip module 200 incorporated in the signaling device 100, the chip module 200 checks (800) one or more fixed seed values stored in the basic setting memory area, (At 805) at least one dynamic seed value for generating a one-off code, and then dynamically generates a one-off code (810) by assigning at least one fixed seed value and at least one dynamic seed value to the designated code generation algorithm. If the disposable code is generated, the chip module 200 generates a default asynchronous radio signal including the disposable code (815).

If the operation mode of the chip module 200 is the vehicle power mode in which the operation is performed by receiving power from the vehicle, the chip module 200 amplifies the basic asynchronous radio signal using the power supplied from the vehicle, Amplified to a pre-calculated output, or amplified to the maximum output available) and broadcast 820.

On the other hand, if the operation mode of the chip module 200 is the charge power mode in which the power charged in the power charging unit 130 is supplied, the chip module 200 broadcasts the basic set asynchronous radio signal in the low power mode (825 ).

The chip module 200 checks 830 whether the setting information generated through the process shown in FIG. 10 is received from the program 325 of the authenticated user terminal 300 through the process shown in FIG. If the setting information is not received, the chip module 200 repeats the broadcasting of the basic asynchronous radio signal more than or a specified number of times.

Meanwhile, when the setting information is received from the program 325 of the authenticated user terminal 300, the chip module 200 stores the value / information included in the setting information in the designated usage definition memory area 835, Defined asynchronous radio signal including the unique information of the setting information and / or using the dynamically generated one-time code using the value included in the setting information (840).

If the operation mode of the chip module 200 is a vehicle power mode in which power is supplied from the vehicle, the chip module 200 amplifies the use-defined asynchronous radio signal using the power supplied from the vehicle, Amplified to a pre-calculated output, or amplified to the maximum output available) and broadcast 845.

On the other hand, if the operation mode of the chip module 200 is a charge power mode in which the power charged in the power charging unit 130 is supplied, the chip module 200 broadcasts the application defined asynchronous radio signal in the low power mode (850 ).

The chip module 200 determines whether to stop broadcasting the use-defined asynchronous radio signal among the broadcasting of the usage-defined asynchronous radio signal (855). If the broadcast interruption of the use-defined asynchronous radio signal is not determined, the chip module 200 repeats the process of broadcasting the use-defined asynchronous radio signal a predetermined number of times or periodically.

Meanwhile, when the broadcast interruption of the use-defined asynchronous radio signal is determined, the chip module 200 performs a process of broadcasting the basic asynchronous radio signal.

9 is a diagram illustrating an asynchronous radio signal broadcasting process of the chip module 200 according to the third embodiment of the present invention.

In more detail, FIG. 9 selectively broadcasts a basic asynchronous radio signal including unique information of the chip module 200 and including a disposable code generated through the chip module 200 according to a power supply state, Defined asynchronous radio signal corresponding to the setting information when the setting information is received from the program 325 of the authenticated user terminal 300 through the process of FIG. 6, It will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention by referring to and / However, the present invention is not limited to the above-described embodiments, The characteristics of the product are not limited.

Referring to FIG. 9, when operation power is supplied to the chip module 200 incorporated in the signaling device 100, the chip module 200 confirms the unique information stored in the basic setting memory area (900). The chip module 200 identifies (905) one or more fixed seed values stored in a default configuration memory area, determines (910) at least one dynamic seed value for generating a one-off code, The one-time code is dynamically generated by substituting the fixed seed value and the at least one dynamic seed value (915). If the one-off code is generated, the chip module 200 generates a default asynchronous radio signal including the disposable code (920).

If the operation mode of the chip module 200 is the vehicle power mode in which the operation is performed by receiving power from the vehicle, the chip module 200 amplifies the basic asynchronous radio signal using the power supplied from the vehicle, Amplified to a pre-calculated output, or amplified to the maximum output available) and broadcast 925.

On the other hand, if the operation mode of the chip module 200 is the recharge power mode in which the power charged in the power charging unit 130 is supplied, the chip module 200 broadcasts the basic setting asynchronous radio signal in the low power mode (930 ).

The chip module 200 checks 935 whether the setting information generated through the process shown in FIG. 10 is received from the program 325 of the authenticated user terminal 300 through the process shown in FIG. If the setting information is not received, the chip module 200 repeats the broadcasting of the basic asynchronous radio signal more than or a specified number of times.

Meanwhile, when the setting information is received from the program 325 of the authenticated user terminal 300, the chip module 200 stores the value / information included in the setting information in the designated usage definition memory area 940, Defined asynchronous radio signal including the unique information of the setting information and / or using the dynamically generated one-time code using the value included in the setting information (945).

If the operation mode of the chip module 200 is a vehicle power mode in which power is supplied from the vehicle, the chip module 200 amplifies the use-defined asynchronous radio signal using the power supplied from the vehicle, Amplified to a pre-calculated output, or amplified to a maximum output that is available), and broadcast (950).

On the other hand, if the operation mode of the chip module 200 is the recharge power mode in which the power charged in the power charging unit 130 is supplied, the chip module 200 broadcasts the application defined asynchronous radio signal in the low power mode (955 ).

The chip module 200 determines whether the use-defined asynchronous radio signal is to be broadcasted while broadcasting the use-defined asynchronous radio signal (960). If the broadcast interruption of the use-defined asynchronous radio signal is not determined, the chip module 200 repeats the process of broadcasting the use-defined asynchronous radio signal a predetermined number of times or periodically.

Meanwhile, when the broadcast interruption of the use-defined asynchronous radio signal is determined, the chip module 200 performs a process of broadcasting the basic asynchronous radio signal.

FIG. 10 is a diagram illustrating a process of providing setting information for broadcasting an application-defined asynchronous radio signal according to an embodiment of the present invention.

In more detail, the program 325 of the authenticated user terminal 300 through the process shown in FIG. 6 generates configuration information and provides the generated configuration information to the chip module 200 of the signaling device 100, And a process of causing the chip module 200 to broadcast a use-defined asynchronous radio signal as in the process shown in FIGS. 7 to 9, and it will be understood by those skilled in the art that, It is possible to refer to and / or modify the FIG. 10 to various implementations of the setup information providing process (for example, omitting some steps or changing the order). However, And the technical features thereof are not limited only by the method shown in FIG.

Referring to FIG. 10, a program 325 of the terminal 300 generates setting information 1000 for controlling a use-defined asynchronous radio signal to be broadcast through the chip module 200 of the signaling device 100. The program 325 of the user terminal 300 can generate the setting information before being authenticated through the process shown in FIG. 6, and after the authentication is performed through the process shown in FIG. 6, Information can be generated. The setting information may be generated by combining at least one or more pieces of information input through a user operation and / or information received from a designated server 370.

When the setting information is generated, the program 325 of the user terminal 300 provides the setting information to the chip module 200 of the communicating signaling device 100 (1005), and the chip module 200 Defined asynchronous radio signal corresponding to the setting information through the process shown in FIGS. 7 to 9.

Meanwhile, after the program module 325 of the user terminal 300 provides the setting information to the chip module 200, a usage definition asynchronous radio signal corresponding to the setting information is broadcast through the chip module 200 (1010).

According to the first signal discrimination embodiment of the present invention, the program 325 of the user terminal 300 is transmitted from the chip module 200 of the signal device 100 through the chip module 200 to the base- Defined asynchronous radio signal corresponding to the setting information is broadcasted, and the received signal transmission information is read out to correspond to the setting information through the chip module 200 Usage Definition It is possible to determine whether an asynchronous radio signal is broadcast or a basic asynchronous radio signal is broadcast.

The program 325 of the user terminal 300 may be connected to the chip module 200 of the signaling device 100 in cooperation with the local communication unit 312 of the terminal 300, (For example, the asynchronous radio signal can be transmitted without pairing and also received by the local communication unit 312 of the terminal 300) received by the local communication unit 312, 200) to determine whether the use-defined asynchronous radio signal corresponding to the setting information is being broadcast or the basic asynchronous radio signal is being broadcast through the chip module (200).

When bidirectional USB data communication is connected between the chip module 200 and the user terminal 300 of the signaling device 100 according to the third signal discrimination embodiment of the present invention, Can confirm whether the cable is disconnected from the USB connector part 125 of the signaling device 100 or the cable is disconnected from the cable communication part 310 to release the cable connection, Defined asynchronous radio signal corresponding to the setting information through the chip module 200 of the signaling device 100 when the cable is disconnected.

According to the fourth signal discrimination embodiment of the present invention, the program 325 of the user terminal 300 can check whether bidirectional short-range wireless communication is possible with the chip module 200, and when the bidirectional short- Defined asynchronous radio signal corresponding to the setting information through the chip module 200 of the device 100 is stopped.

According to the fifth signal discrimination embodiment of the present invention, the program 325 of the user terminal 300 may be implemented by combining two or more of the first to fourth signal discrimination embodiments to the chip module 200 ), It is possible to determine whether the basic asynchronous radio signal is being broadcast (or the broadcast interruption of the use-defined asynchronous radio signal) or the use-defined asynchronous radio signal corresponding to the setting information is being broadcast, whereby the present invention is not limited No.

If it is determined through the chip module 200 of the signaling device 100 that the use-defined asynchronous radio signal is being broadcast through the first to fifth signal discrimination examples, the program 325 of the user terminal 300, (1015) the information corresponding to the usage definition asynchronous radio signal broadcasting.

On the other hand, through the first to fifth signal discrimination examples, it is confirmed that the broadcast of the use-defined asynchronous radio signal is stopped through the chip module 200 of the signaling device 100, The program 325 of the user terminal 300 outputs information corresponding to the broadcast stop of the use definition asynchronous radio signal (or broadcast of the default asynchronous radio signal) (1020).

11 is a diagram illustrating a process of selectively activating / deactivating the bi-directional USB data communication function of the chip module 200 according to an embodiment of the present invention.

More specifically, FIG. 11 illustrates a process of selectively activating or deactivating the bi-directional USB data communication function of the chip module 200 according to the power supply state of the chip module 200 and whether or not the bi-directional short-range wireless communication is performed. Those skilled in the art will be able to refer to and / or modify Figure 11 to illustrate various implementations of the bi-directional USB data communication function activation / deactivation process of the chip module 200 It is to be understood that the invention may be practiced otherwise than as specifically described herein, but it is to be understood that the invention is not limited to the disclosed embodiments, .

Referring to FIG. 11, when the operation mode of the chip module 200 is set or confirmed as one of the vehicle power mode and the recharge power mode through the process shown in FIG. 4, (Step 1100). If the paired user terminal 300 is confirmed, the chip module 200 connects the paired user terminal 300 with the bi-directional short-range wireless communication (1105). When the operation mode of the chip module 200 is the vehicle power mode during or after the connection of the bidirectional short-range wireless communication with the user terminal 300, that is, when the bidirectional short-range wireless communication is connected in the vehicle power mode, 200 deactivates the bi-directional USB data communication function (1110).

If the paired user terminal 300 is not acknowledged (e.g., the paired user terminal 300 is out of the two-way short range wireless communication or the short-range wireless communication function of the user terminal 300 is disabled) The chip module 200 activates the bidirectional USB data communication function 1115 and transmits the bi-directional USB data communication function to the USB connector unit 125 of the signaling device 100, (1120) whether the user terminal (300) and the cable are connected to each other. If a cable is connected to the user terminal 300, the chip module 200 connects bi-directional USB data communication with the user terminal 300 (1125).

100: Signal device 105: Body part
110: Terminal 115: Power supply
120: power conversion unit 125: USB connector unit
130: Power charging unit 200: Chip module
204: USB communication unit 212: RF processing unit
224: terminal registration unit 228: terminal authentication unit
232: PIN registration unit 236: PIN authentication unit
240: communication processing unit 244: module authentication processing unit
248: Information storage unit 252: Seed storage unit
256: Seed decision unit 260: Code generation unit
264: Signal sending part 268: Power source confirming part
272: Mode setting section 276: Signal control section
280: USB control unit 284:
300: Terminal 325: Program

Claims (25)

A vehicle-mounted signal device capable of supplying power to a vehicle,
A power supply unit for receiving power supplied from a vehicle;
A power converter for converting the power supplied from the vehicle into a specified operating power; And
Wherein the power supply unit is operated through an operation power source that converts vehicle power supplied from the vehicle when power supply from the vehicle is confirmed through the power supply unit,
At least one bi-directional data communication comprising WiFi communication with the paired user terminal,
And a chip module for broadcasting an asynchronous radio signal to the outside using the vehicle power source.
The method according to claim 1,
Further comprising a power charging unit charging at least one of a power source supplied through the power supply unit or a power source converted through the power conversion unit,
Wherein the chip module operates using the charging power charged in the power charging unit when power supply to the vehicle is not confirmed.
The method according to claim 1,
And a USB connector for supplying a USB (Universal Serial Bus) power converted through the power conversion unit to an external device, wherein the USB connector unit transmits the asynchronous radio signal.
The semiconductor integrated circuit device according to claim 3,
And a USB communication unit electrically connected to the USB connector unit to process the USB-based data communication, wherein the USB communication unit transmits the asynchronous radio signal.
The semiconductor integrated circuit device according to claim 3,
Wherein the bidirectional USB-based data communication is performed with the user terminal when the user terminal is connected to the USB connector unit.
6. The semiconductor memory device according to claim 5,
And a USB controller for activating the USB-based data communication when the bidirectional short-range wireless communication with the user terminal is performed while operating through the vehicle power supplied from the vehicle. Type signal device.
The chip module according to claim 1,
A memory unit having an identification information storage area for storing terminal identification information for uniquely identifying and authenticating a user terminal (or a program of a user terminal); And
And a terminal registration unit for receiving the terminal identification information from the user terminal and registering the terminal identification information in the identification information storage area when the bidirectional data communication is established with the user terminal. Signal device.
8. The semiconductor memory device according to claim 7,
A terminal authenticating unit for authenticating the validity of a user terminal (or a program of a user terminal) connected in bidirectional data communication using the terminal identification information when the terminal identification information is registered in a bidirectional data communication connection with the user terminal; And
And a communication processor for processing bidirectional data communication with the terminal authenticated through the terminal identification information. ≪ Desc / Clms Page number 19 >
The chip module according to claim 1,
A memory unit having a PIN storage area for storing PIN authentication information for PIN authentication; And
A PIN registration unit for registering PIN authentication information from a user terminal connected to bidirectional data communication and storing the PIN authentication information in the PIN storage area; And
And a PIN authentication unit for receiving the PIN information input through the user terminal connected to the bidirectional data communication and authenticating the PIN information through the PIN authentication information. .
The chip module according to claim 1,
A memory unit having a basic setting memory area for storing a data set for broadcasting a basic asynchronous radio signal and a use definition memory area for storing a data set for broadcasting an asynchronous radio signal that is defined by the user terminal Wherein the asynchronous radio signal is transmitted to the base station.
The chip module according to claim 1,
An information storage unit for storing unique information to be broadcast through a predetermined asynchronous radio signal in a designated basic setting memory area; And
Further comprising: a signal transmission unit for broadcasting an asynchronous radio signal including unique information of the basic setting memory region to broadcast the asynchronous radio signal.
The chip module according to claim 1,
A seed storage unit for storing at least one fixed seed value for generating a one-time code to be broadcast through a predetermined asynchronous radio signal in a designated basic setting memory area;
A seed determining unit for determining at least one dynamic seed value for generating the disposable code;
A code generator for assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm to dynamically generate a one-time code; And
And a signal transmitting unit for controlling an asynchronous radio signal including the disposable code to be broadcasted. ≪ Desc / Clms Page number 19 >
The chip module according to claim 1,
An information storage unit for storing unique information to be broadcast through a predetermined asynchronous radio signal in a designated basic setting memory area;
A seed storage unit for storing at least one fixed seed value for generating a one-time code to be broadcast through a predetermined asynchronous radio signal in the basic setting memory area;
A seed determining unit for determining at least one dynamic seed value for generating the disposable code;
A code generator for assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm to dynamically generate a one-time code; And
And a signal transmitting unit for broadcasting an asynchronous radio signal including the unique information of the basic setting memory region and the disposable code.
The semiconductor integrated circuit according to claim 2,
A power supply confirmation unit for confirming a state of supplying vehicle power from the vehicle; And
And a control unit for setting or checking a vehicle power mode operated by using the vehicle power when the vehicle power supply is confirmed and setting or confirming a charging power mode operated by using the charging power supplied to the power charging unit And a mode setting unit for setting a mode of the asynchronous radio signal based on the received signal.
The chip module according to claim 1,
Further comprising a signal controller for controlling the broadcasting of the asynchronous radio signal by amplifying the asynchronous radio signal to a predetermined output or a maximum output in a usable range when the vehicle is powered on and supplying the asynchronous radio signal. Type signal device.
The semiconductor integrated circuit according to claim 2,
Further comprising a signal controller for controlling the asynchronous radio signal to be broadcast at a low power output upon receipt of the charging power supply.
The chip module according to claim 1,
A communication processing unit for receiving configuration information for selectively broadcasting a use-defined asynchronous radio signal from a user terminal through bidirectional data communication; And
And a transmission control unit for controlling the use-defined asynchronous radio signal corresponding to the setting information to broadcast the asynchronous radio signal.
18. The method according to claim 17,
Usage Definition Unique information to be included in the asynchronous radio signal,
Usage Definition A seed value for generating a one-off code to be included in an asynchronous radio signal,
And a protocol structure of an asynchronous radio signal, and a protocol structure of a usage definition asynchronous radio signal.
18. The semiconductor memory device according to claim 17,
An information storage unit for storing the unique information included in the setting information in a designated usage definition memory area; And
And a signal transmission unit for broadcasting a use-defined asynchronous radio signal including unique information stored in the usage definition memory area to broadcast the asynchronous radio signal.
18. The semiconductor memory device according to claim 17,
A seed storage unit for storing at least one seed value included in the setting information in a designated usage definition memory area;
A seed determining unit for determining one or more seed values for generating the disposable code;
A code generator for assigning one or more seed values to a designated code generation algorithm to dynamically generate a single use code; And
And a signal transmission unit for broadcasting a use-defined asynchronous radio signal including the disposable code to broadcast the asynchronous radio signal.
18. The semiconductor memory device according to claim 17,
An information storage unit for storing the unique information included in the setting information in a designated usage definition memory area;
A seed storage unit for storing at least one seed value included in the setting information in the usage definition memory area;
A seed determining unit for determining one or more seed values for generating the disposable code;
A code generator for assigning one or more seed values to a designated code generation algorithm to dynamically generate a single use code; And
And a signal transmission unit for broadcasting an asynchronous radio signal including unique information stored in the usage definition memory area and the generated disposable code. Signal device.
The apparatus according to claim 17,
Wherein the determination unit determines whether to broadcast a usage definition asynchronous radio signal according to a control command of a user terminal connected to the bidirectional data communication.
The apparatus according to claim 17,
Defined asynchronous radio signal is broadcast based on whether or not bidirectional short-range wireless communication with the user terminal is impossible in a state where valid setting information is stored in a designated usage definition memory area. The adaptive signal device comprising:
The apparatus according to claim 17,
Definition information is stored in a designated usage definition memory area, and at the same time, the use-defined asynchronous radio signal is broadcast, but when a specified valid time has elapsed or when a specific signal is received from the user terminal, Wherein the control unit controls the transmission of the asynchronous radio signal.
18. The communication system according to claim 17,
And transmits signal transmission information corresponding to a state of broadcasting the asynchronous radio signal of one of the basic setting asynchronous radio signal and the using asynchronous radio signal to the user terminal through bidirectional data communication. An adaptive signaling device for vehicle mounting.

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