KR20200004992A - Adaptive Hi-Pass Terminal - Google Patents

Abstract

According to the present invention, an adaptive Hi-pass terminal comprises: a power supply unit configured to receive vehicle power; a power conversion unit configured to convert the vehicle power into at least one operating power; a card leader unit operated by the operating power converted for an IC chip, and configured to read an IC chip of a Hi-pass card in a contact manner; a first wireless module operated through the operating power converted to correspond to a first radio signal, and configured to perform a designated operation for transmitting and receiving the first radio signal of a preset first radio frequency band to and from a roadside base station installed on a designated road; a first antenna unit operated through the operating power corresponding to the first radio signal, and configured to transmit and receive the first radio signal on the basis of the designated operation of the first wireless module; and a Hi-pass module operated through the designated operating power, and configured to perform a Hi-pass payment procedure by interworking with the IC chip of a Hi-pass card through the card reader unit and interworking with the roadside base station through the first wireless module. The adaptive Hi-pass terminal may further comprise: a second wireless module operated through the designated specific operating power, and configured to transmit a basically set second radio signal of a second radio frequency band different from the first radio frequency band, wherein the second wireless module performs a designated operation to selectively transmit the second radio signal of which usage is defined through a user terminal; and a second antenna unit operated through the specific operating power, and configured to transmit the second radio signal on the basis of the designated operation of the second wireless module. According to the present invention, the Hi-pass terminal can be widely used for additional purposes at a tollgate or in a Hi-pass section.

Description

Adaptive Hi-Pass Terminal

The present invention relates to an adaptive high-pass terminal, the adaptive high-pass terminal according to the present invention, a power supply unit for receiving vehicle power, a power conversion unit for converting the vehicle power into one or more operating power, IC chip for The card reader unit, which is operated by the converted operating power source and contacts with the IC chip of the Hi-Pass card, is operated by the converted operating power source corresponding to the first wireless signal, and operates on the road of the designated road. A first radio module performing a specified operation for transmitting and receiving a first radio signal of a preset first radio frequency band with an installed on-vehicle base station, and operating through an operation power source corresponding to the first radio signal, and the first radio module A first antenna unit for transmitting and receiving a first wireless signal based on a specified operation of the first antenna unit; A high pass module which interworks with an IC chip of a pass card and performs a high pass payment procedure by interworking with a roadside base station through the first radio module, and a second pass that is operated through a specified specific operating power source and is different from the first radio frequency band; A second wireless module which transmits a basic second radio signal of a radio frequency band and performs a designated operation for selectively transmitting a purpose-defined second radio signal through a user terminal; And a second antenna unit configured to transmit a second radio signal based on a specified operation of the second radio module.

Recently, many drivers on highways have been using high passes. High Pass is a system that uses a wireless communication network to settle and settle the tolls in a driving vehicle.In general, when a driver passes the toll gate's high-pass antenna with the high-pass card inserted in the terminal, the payment information is displayed. The method is recorded on the terminal.

Korean Patent Laid-Open Publication No. 10-2013-0001598 (published Jan. 4, 2013) relates to a high pass card, and a high pass card inserted and used in a high pass terminal is disclosed.

However, such a conventional high pass terminal is used only for high pass payment by inserting a high pad, and does not additionally provide other functions.

Meanwhile, various services (eg, order / payment, access / authentication, membership service, etc.) using Bluetooth beacons have recently been provided. In particular, as vehicle technology and IoT technology are combined, various services are required in vehicles.

An object of the present invention for solving the above problems, the power supply unit for receiving the vehicle power, a power conversion unit for converting the vehicle power to one or more operating power, and operating through the operating power converted for the IC chip A card reader unit contacting with an IC chip of a Hi-Pass card, a road base station installed on a road of a designated road and operating through a power supply converted to correspond to a first wireless signal, and a preset first A first radio module performing a specified operation to transmit and receive a first radio signal in a radio frequency band, and a first radio based on a specified operation of the first radio module and operating through an operation power source corresponding to the first radio signal; A first antenna unit for transmitting and receiving a signal, and operating through a designated operating power source and interworking with the IC chip of the high pass card through the card reader unit; 1 A high pass module for performing a high pass payment procedure by interworking with a road station base station through a wireless module, and a second radio signal which is operated through a specified specific operating power source and is a second set of radio signals different from the first radio frequency band. A second wireless module for performing a specified operation to selectively transmit a second defined wireless signal for use through a user's terminal and a specific operation power source and based on a specified operation of the second wireless module. The present invention provides an adaptive high pass terminal including a second antenna unit for transmitting a radio signal.

The adaptive high pass terminal according to the present invention includes a power supply unit for receiving vehicle power, a power conversion unit for converting the vehicle power into one or more operating powers, and an operating power source converted for an IC chip and operating through a high pass ( Hi-Pass) The card reader unit contacting with the IC chip of the card, the road base station installed on the road of the designated road and operating through the operating power source converted to correspond to the first radio signal and the preset first radio frequency band A first wireless module performing a specified operation for transmitting and receiving a first wireless signal of the first wireless signal, and operating through an operating power source corresponding to the first wireless signal, and transmitting and receiving a first wireless signal based on a specified operation of the first wireless module It operates through a first antenna unit and a designated operating power source and interworking with the IC chip of the high pass card through the card reader unit and the first wireless module A high pass terminal having a high pass module for performing a high pass payment procedure in association with a road station base station, the high pass terminal operating through a specified specific operating power source and configured as a default setting of a second radio frequency band different from the first radio frequency band. A second wireless module that transmits a wireless signal, and performs a specified operation to selectively transmit a second defined wireless signal that is purpose-defined through a user's terminal, and operates through the specific operation power source and performs a specified operation of the second wireless module It characterized in that it comprises a second antenna unit for transmitting a second wireless signal based on.

In the adaptive high pass terminal according to the present invention, the first radio signal is characterized in that it comprises a radio frequency signal for transmitting and receiving in a dedicated short-range communication (DSRC) method of the 5.9GHz band.

In the adaptive high pass terminal according to the present invention, the second radio module transmits a basic radio signal of a second radio frequency band different from the first radio frequency band so as not to interfere with the first radio signal. However, it is characterized in that for performing a specified operation for selectively transmitting the purpose-defined second radio signal through the user's terminal so as not to interfere with the first radio signal.

In the adaptive high pass terminal according to the present invention, the second radio module is configured to receive a second radio signal of a second radio frequency band in which frequency interference with the first radio frequency band is minimized among two or more radio frequency bands that can be transmitted. It is characterized in that the oscillating and transmitting operation.

In the adaptive high pass terminal according to the present invention, the second radio module includes a BLE chip capable of transmitting a BLE (Bluetooth Low Energy) signal, and the second radio signal of the second radio frequency band is a specified signal. Characterized in that it comprises a BLE signal of strength.

In the adaptive high pass terminal according to the present invention, the specific operating power source includes a power source converted from the vehicle power source to amplify and transmit a second radio signal of the second radio frequency band to a specified signal intensity. It is characterized by.

In the adaptive high pass terminal according to the present invention, when the second wireless module is a BLE (Bluetooth Low Energy) module, the voltage of the specific operating power source conforms to the BLE standard, but the specific operation The current of the power source is characterized in that it comprises a power source converted to a certain ratio larger than the current of the BLE standard.

In the adaptive high pass terminal according to the present invention, the high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that faces the vehicle front direction, and the second antenna unit is configured based on the vehicle front direction. It is characterized in that it is disposed so as not to overlap with the antenna unit.

In the adaptive high pass terminal according to the present invention, the high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that faces the vehicle front direction, and the second antenna unit is in a predetermined angle upper direction in the vehicle front direction. It is characterized in that it is disposed so as not to overlap with the first antenna unit.

In the adaptive high pass terminal according to the present invention, the high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that is oriented at a predetermined angle in the upper direction of the vehicle front direction, and the second antenna unit is positioned in the vehicle front direction. Characterized in that not to overlap the first antenna portion on the basis of a predetermined angle of the upper direction.

In the adaptive high pass terminal according to the present invention, the high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that is oriented at a predetermined angle in the upper direction of the vehicle front direction, and the second antenna unit is positioned in the vehicle front direction. It is characterized in that it is disposed so as not to overlap with the first antenna unit.

In the adaptive high pass terminal according to the present invention, the mounting form is characterized in that it comprises a form attached to the front glass of the vehicle or the form attached to the dashboard of the vehicle.

In the adaptive high pass terminal according to the present invention, the second wireless module includes a PIN storage area for storing PIN authentication information and an authentication information storage area for storing unique authentication information for authenticating a terminal (or program) that is a valid communication target. Check whether valid PIN authentication information is registered in the PIN storage area when communicating with the memory unit and the terminal, and if the PIN authentication information is not registered, register the PIN authentication information from the terminal to the PIN storage area. When PIN authentication information is registered in the PIN storage area when communicating with the PIN registration unit and the terminal to save, check whether valid unique authentication information is registered in the authentication information storage area, and if the unique authentication information is not registered, The PIN authentication unit and the unique authentication information for performing the PIN authentication procedure for the terminal using the registered PIN authentication information When PIN authentication in a non-locked state accepted provided the unique identification information from the PIN authenticated terminal characterized by comprising an authentication information registration unit for registering in the authentication information storage.

In the adaptive high-pass terminal according to the present invention, the second wireless module is characterized in that it communicates with the terminal of the user via a two-way short-range wireless communication connected to the terminal of the user in accordance with a specified pairing procedure.

In the adaptive high pass terminal according to the present invention, the bidirectional short range wireless communication is characterized by including Bluetooth communication based on Bluetooth pairing.

In the adaptive high-pass terminal according to the present invention, the terminal authentication for authenticating the validity of the terminal (or a program mounted on the terminal) by using the unique authentication information when the communication connection with the terminal in the unique authentication information registered state And a communication processing unit communicating with a terminal authenticated through the unique authentication information.

In the adaptive high pass terminal according to the present invention, the PIN authentication unit performs a PIN authentication procedure for adding or updating the unique authentication information, the authentication information registration unit, the unique authentication information from the PIN authenticated terminal It is characterized in that the addition or update to the authentication information storage area received.

In the adaptive high pass terminal according to the present invention, the second wireless module includes a basic memory area for storing a data set for transmitting a basic second wireless signal and a second wireless use defined through an authenticated terminal. And a memory unit having a defined memory area for storing data sets for transmitting signals.

In the adaptive high-pass terminal according to the present invention, the second wireless module, the information storage unit for storing the unique information to be transmitted through the second basic radio signal set in the basic setting memory area and the basic setting memory area And a signal transmitter for transmitting a second radio signal including the unique information.

In the adaptive high-pass terminal according to the present invention, the second wireless module, the seed for storing at least one fixed seed value for generating a one-time code to be transmitted through the second default radio signal set in the basic memory area; A code determining unit for determining at least one dynamic seed value for generating a storage unit and the disposable code, and a code for dynamically generating a disposable code by assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm. And a signal transmitter for transmitting a second wireless signal including the generator and the disposable code.

In the adaptive high-pass terminal according to the present invention, the second wireless module, an information storage unit for storing the unique information to be transmitted through the default second radio signal in the basic memory area and the default second radio signal A seed storage unit for storing at least one fixed seed value for generating a disposable code to be transmitted through the basic setting memory area, and a seed determination unit for determining at least one dynamic seed value for generating the disposable code; A code generator for dynamically generating a disposable code by substituting one or more fixed seed values and at least one dynamic seed value into a generation algorithm, and transmitting a second radio signal including the unique information of the basic memory area and the disposable code; And a signal transmitter.

In the adaptive high-pass terminal according to the present invention, the second wireless module, the second wireless signal of the second wireless signal to reach a certain distance outside the vehicle beyond the front glass of the vehicle or beyond the vehicle side of the vehicle And a signal controller for controlling to amplify and transmit the signal strength.

In the adaptive high pass terminal according to the present invention, the second wireless module checks whether a first wireless signal is transmitted in cooperation with the first wireless module, and transmits a first wireless signal through the first wireless module. And a signal controller for controlling the transmission of the second radio signal to be temporarily suspended.

In the adaptive high pass terminal according to the present invention, the second wireless module checks whether a first wireless signal is transmitted in cooperation with the first wireless module, and transmits a first wireless signal through the first wireless module. And a signal controller configured to control the signal intensity of the second wireless signal to be amplified and transmitted by a predetermined ratio or more.

In the adaptive high-pass terminal according to the present invention, the second wireless module receives the usage definition information for selectively transmitting the use-defined second wireless signal through the second wireless module from the terminal effectively connected to the communication. And a sending control section for controlling to send a use-defined second radio signal corresponding to the use definition information.

In the adaptive high-pass terminal according to the present invention, the use definition information, the unique information to be included in the use definition second radio signal, the seed value for generating a one-time code to be included in the use definition second radio signal, use definition second Characterized in that it comprises at least one of the protocol structure of the radio signal.

In the adaptive high pass terminal according to the present invention, the second wireless module includes an information storage unit for storing the unique information included in the definition information in the definition memory area and the unique information of the definition memory area. It characterized in that it comprises a signal transmitting unit for transmitting a second wireless signal to include.

In the adaptive high pass terminal according to the present invention, the second wireless module generates a seed storage unit and the disposable code for storing one or more fixed seed values included in the definition information in the definition memory area. And a seed generator for determining at least one dynamic seed value, a code generator for dynamically generating a disposable code by assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm, and the disposable code. And a signal transmitter for transmitting the second radio signal.

In the adaptive high pass terminal according to the present invention, the second wireless module includes an information storage unit for storing the unique information included in the definition information in the definition memory area and at least one included in the definition information. A seed storage unit for storing a fixed seed value in the use-defined memory region, a seed determination unit for determining at least one dynamic seed value for generating the disposable code, and at least one fixed seed value and at least one of And a signal generator for dynamically generating a disposable code by substituting a dynamic seed value and a signal transmitter for transmitting a second radio signal including the unique information of the application-defined memory area and the disposable code.

In the adaptive high-pass terminal according to the present invention, the transmitting control unit determines whether the bidirectional short-range wireless communication is possible with the terminal while transmitting the use-defined second radio signal, and the bidirectional short-range wireless communication is impossible. In this case, it is characterized in that the control to transmit the default second radio signal.

In the adaptive high-pass terminal according to the present invention, the transmission control unit determines whether or not the bidirectional short-range wireless communication with the terminal is possible while transmitting the use-defined second radio signal, when the bidirectional short-range wireless communication is possible And control to transmit the use-defined second radio signal.

In the adaptive high-pass terminal according to the present invention, the communication processing unit, the signal transmission information corresponding to the state of transmitting any one of the basic setting second radio signal and the use-defined second radio signal of the second radio signal; Characterized in that provided to the terminal.

According to the present invention, by providing an adaptive high-pass terminal, there is an advantage that can be used for various purposes such as parking, fueling, vehicle tracking in addition to the high-pass payment, and also in addition to the high-pass payment, alternative payment when the balance of the high pass card is insufficient In addition, there is an advantage that can be used for additional purposes, such as additional services that can be provided in the toll gate or high pass section, such as payment of unpaid fees.

1 is a diagram illustrating a configuration of an adaptive high pass terminal according to an embodiment of the present invention.
2 is a diagram illustrating a process of transmitting a first radio signal and a second radio signal through an adaptive high pass terminal according to an exemplary embodiment of the present invention.
3 is a diagram illustrating a process of transmitting a first radio signal and a second radio signal through an adaptive high pass terminal according to another exemplary embodiment of the present invention.
4 is a diagram illustrating a PIN authentication or unique authentication information registration process according to an embodiment of the present invention.
5 is a diagram illustrating a process of authenticating a second wireless module of a terminal (or program) authentication or an adaptive high pass terminal according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating a second radio signal transmission process through a second radio module of the adaptive high pass terminal according to the first embodiment of the present invention.
7 is a diagram illustrating a process of transmitting a second radio signal through a second radio module of the adaptive high pass terminal according to the second embodiment of the present invention.
8 is a diagram illustrating a process of transmitting a second radio signal through a second radio module of the adaptive high pass terminal according to the third embodiment of the present invention.
9 is a diagram illustrating a process of providing usage definition information to a second wireless module of an adaptive high pass terminal according to an exemplary embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings and description will be described in detail the operating principle of the preferred embodiment of the present invention. However, the drawings and the following description shown below are for the preferred method among various methods for effectively explaining the features of the present invention, the present invention is not limited only to the drawings and description below.

That is, the following embodiments correspond to embodiments of the preferred union form among many embodiments of the present invention, and embodiments or omit specific configurations (or steps) in the following embodiments. An embodiment of dividing a function implemented in a specific configuration (or step), or an embodiment, a specific configuration (or step) incorporating a function implemented in two or more configurations (or steps) into one configuration (or step). Embodiments to replace the order of operation, etc., unless explicitly stated otherwise in the following examples will be apparent that all belong to the scope of the present invention. Therefore, it is to be noted that various embodiments corresponding to a subset or a filter based on the following examples may be divided retrospectively according to the filing date of the present invention.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. It is only.

1 is a diagram illustrating a configuration of an adaptive high pass terminal according to an embodiment of the present invention.

More specifically, FIG. 1 shows a first radio signal of a preset first radio frequency band interlocked with a road base station installed on a road of a designated road after being mounted in a vehicle, supplied with vehicle power, and contacted with an IC chip of a high pass card. Performing a high-pass payment procedure, and transmitting a second radio signal of a second radio frequency band different from the first radio frequency band so as not to interfere with the first radio signal, and using the user-defined terminal A configuration of an adaptive high pass terminal 100 for selectively transmitting a radio signal, and a person of ordinary skill in the art to which the present invention pertains may refer to and / or modify the drawing 1 and the high pass. It is possible to infer various implementation methods for the terminal 100 (eg, implementation methods in which some components are omitted, subdivided, or combined). The present invention includes all the inferred implementation methods, and the technical features are not limited only to the implementation method illustrated in FIG.

Referring to FIG. 1, the adaptive high pass terminal 100 may be attached to a front glass or a room mirror in a vehicle, and communicates with a roadside base station installed in an upward direction of the front of the vehicle when entering the toll gate to process a high pass payment. To this end, the power supply unit 125 receives the vehicle power, the power conversion unit 130 for converting the vehicle power into one or more operating powers, and the operating power converted for the IC chip, and operates through a high pass (Hi). -Pass) The card reader unit 105, which is in contact with the IC chip of the card, and the on-board base station installed on the road of the designated road and operated by the operating power source converted to correspond to the first radio signal and the preset first radio A first wireless module 115 performing a designated operation for transmitting and receiving a first wireless signal in a frequency band, and operating through an operating power source corresponding to the first wireless signal, 1 operates through a first antenna unit 120 for transmitting / receiving a first radio signal based on a specified operation of the wireless module 115 and a designated operating power source, and communicates with the IC chip of the high pass card through the card reader unit 105. It may be configured to include a high-pass module 110 for interworking and performing a high-pass payment procedure in conjunction with the road-to-base station through the first wireless module 115.

Here, the first radio signal may include a radio frequency signal for transmitting and receiving in a dedicated short-range communication (DSRC) method of the 5.9GHz band.

Here, the power conversion unit 130 does not convert the vehicle power (for example, a general vehicle DC 12V, DC 24V, etc. in the case of a large vehicle such as a large truck) into any one operating power, to suit each functional component It is possible to convert to more than one operating power source.

The high-pass terminal 100 according to the present invention operates through a specified specific operating power source and transmits a default second radio signal of a second radio frequency band different from the first radio frequency band, but not by the user's terminal (not shown). A second wireless module 140 performing a specified operation for selectively transmitting a purpose-defined second wireless signal through a), and operating through the specific operating power source and performing a specified operation of the second wireless module 140. It may be configured to further include a second antenna unit 135 for transmitting a second wireless signal based on.

The user's terminal may include a designated Bluetooth enabled terminal (eg, a mobile terminal owned by a user, a mobile phone, a smartphone, a tablet PC, etc.) located at a short distance through a Bluetooth based short range communication function.

According to the present invention, the second radio module 140 transmits a basic second radio signal of a second radio frequency band different from the first radio frequency band so as not to interfere with the first radio signal, but not to the user's terminal. In order to selectively transmit the defined second radio signal without interfering with the first radio signal, a designated operation may be performed.

In addition, the second radio module 140 operates to selectively oscillate and transmit a second radio signal of a second radio frequency band in which frequency interference with the first radio frequency band is minimized among two or more radio frequency bands that can be transmitted. Can be done.

According to a first embodiment of transmitting the second radio signal, the second radio module 140 is a second radio frequency determined to minimize frequency interference with the first radio frequency band among two or more radio frequency bands that can be transmitted. The second radio signal of the band may be oscillated.

According to a second embodiment of transmitting the second radio signal, the second radio module 140 may include a second radio frequency band that minimizes frequency interference with the first radio frequency band among two or more radio frequency bands that can be transmitted. The second radio signal may be selectively adaptively oscillated.

According to the embodiment of the present invention, the second wireless module 140 includes a BLE module capable of transmitting a Bluetooth Low Energy (BLE) signal, and the second wireless signal of the second radio frequency band has a specified signal strength. It may include a BLE signal, but is not limited thereto. For example, the second radio module 120 may include a chip corresponding to other radio signal means capable of transmitting in addition to the BLE, and the second radio signal of the second radio frequency band through the other radio signal means may be a designated signal. It may include a wireless signal of strength.

According to the present invention, a specific operating power source for operating the second radio module 140 includes a power source converted from the vehicle power source to amplify and transmit the second radio signal of the second radio frequency band to a specified signal intensity. can do. For example, when the second wireless module is a Bluetooth Low Energy (BLE) module, the voltage of the specific operating power source conforms to the BLE standard, but the current of the specific operating power source is converted by a certain ratio greater than the current of the BLE standard. It may include.

According to the present invention, the second antenna unit 135 for transmitting a second radio signal based on the specified operation of the second radio module 140 may be formed in various forms according to the vehicle mounting position of the high pass terminal 100. The first antenna unit 120 may be disposed so as not to overlap.

According to the first exemplary embodiment of the arrangement of the second antenna unit 135, when the high pass terminal 100 is mounted on a designated portion inside the vehicle in a mounting form facing the vehicle front direction (for example, the high pass) When the terminal is mounted in a room mirror inside the vehicle), the second antenna unit 135 may be disposed so as not to overlap with the first antenna unit 120 based on the front direction of the vehicle.

According to the second exemplary embodiment of the arrangement of the second antenna unit 135, when the high pass terminal 100 is mounted on a designated portion inside the vehicle in a mounting form facing the vehicle front direction (for example, the high pass) When the terminal is mounted in a room mirror inside the vehicle), the second antenna unit 135 may be disposed so as not to overlap the first antenna unit 120 based on a predetermined angle of the upper direction of the vehicle front direction. For example, since the antenna of the on-road base station communicating with the high-pass terminal is generally provided above the predetermined height on the road, the second antenna unit 135 has a length in the front direction corresponding to a predetermined height provided with the antenna of the on-road base station. The second wireless signal may be transmitted without interference of the wireless signal when the first antenna unit 120 does not overlap with respect to the upper direction.

According to the third embodiment of the arrangement of the second antenna unit 135, when the high-pass terminal 100 is mounted on a designated portion inside the vehicle in a mounting form for directing a predetermined angle of the upper direction of the vehicle front direction (For example, when the mounting form of the high-pass terminal is a mounting form attached to the windshield of the vehicle or attached to the dashboard), the second antenna unit 135 is based on a predetermined angle upper direction of the vehicle front direction. The first antenna unit 120 may be disposed so as not to overlap.

According to the fourth embodiment of the arrangement of the second antenna unit 135, when the high pass terminal 100 is mounted on a designated portion inside the vehicle in a mounting form that is oriented at a predetermined angle upward direction in the front direction of the vehicle. (For example, when the mounting form of the high-pass terminal is a mounting form attached to the windshield of the vehicle or attached to the dashboard), the second antenna unit 135 is based on the front direction of the vehicle, the first antenna unit 120 ) So that they do not overlap.

Referring to FIG. 1, the second wireless module 140 includes a control unit 145 for controlling the operation of the second wireless module 140 and a data set necessary for the operation of the second wireless module 140. Or a memory unit 155 for storing a program code) and an RF processor 150 for performing RF processing for transmitting the second radio signal.

The second wireless module 140 may be manufactured in the form of one or more SMD (Surface Mount Devices) for beacon operation on a printed circuit board (PCB), the control unit 145, the memory unit 155 and The RF processor 150 may be implemented in the form of an integrated chip having a beacon function, or in the form of an individual device mounted on a PCB, or a combination of an integrated chip and each device.

The controller 145 is a generic term for a configuration of controlling the operation of the second wireless module 140, and may include at least one processor and an execution memory, and may be provided in the second wireless module 140. Each component can be connected via a bus. According to the present invention, the controller 145 loads at least one program code included in the second wireless module 140 through the processor into the execution memory, and calculates at least one result through the bus. By transmitting to the component of the control of the operation of the second wireless module 140. Hereinafter, for convenience, a program configuration implemented in the second wireless module 140 in the form of program code will be described in the controller 145.

The memory unit 155 is a general term for a nonvolatile memory included in the second wireless module 140, and at least one program code executed through the controller 145 and at least one data used by the program code. You can save and maintain the set. The memory unit 155 may basically store a system program code and a system data set corresponding to an operating system of the second wireless module 140, and at least one application program code and an application data set. Program codes and data sets corresponding to the data may also be stored in the memory unit 155.

According to the exemplary embodiment of the present invention, the memory unit 155 may include a basic memory area for storing a data set for transmitting a basic Bluetooth-based second wireless signal.

According to the exemplary embodiment of the present invention, the memory unit 155 may include a definition memory area for storing a data set for transmitting a defined Bluetooth-based second wireless signal through a terminal of an authenticated user.

According to an embodiment of the present invention, the memory unit 155 may include a PIN storage area for storing PIN authentication information for performing a PIN (Personal Identification Number) authentication procedure.

According to an embodiment of the present invention, the memory unit 155 may include an authentication information storage area for storing unique authentication information for uniquely identifying and authenticating a terminal (or a program mounted on the terminal) of a user that is a valid communication target. .

According to the exemplary embodiment of the present invention, the memory unit 155 may store module authentication information for allowing an authenticated user's terminal to uniquely identify / authenticate the second wireless module 140.

The RF processor 150 is a generic term for a configuration for performing RF processing (for example, radio frequency signal modulation, etc.) for transmitting a second radio signal in the form of a radio frequency signal through the second antenna unit 135. The second radio signal of the standard may be periodically transmitted. Preferably, the RF processing unit 150 may broadcast the second radio signal without identifying or pairing a receiver that receives the radio frequency signal.

Meanwhile, according to the extended embodiment of the present invention, the second wireless module 140 may have a Bluetooth-based short-range communication function in addition to a function of transmitting a second wireless signal. For example, the second wireless module 140 may be a designated Bluetooth enabled terminal (eg, a mobile terminal owned by a user, a mobile phone, a smartphone, a tablet PC, etc.) and a Bluetooth-based short-range located at a short distance through a Bluetooth-based short-range communication function. Communication can be performed. In this case, the RF processor 150 may perform RF processing for Bluetooth-based short-range communication.

Referring to FIG. 1, in more detail, the second radio module 140 transmits a second radio signal of a second radio frequency band different from the first radio frequency band to a first radio signal of the first radio module 115. In order to transmit without interference, the PIN registration unit 160, the authentication information registration unit 162, and a signal transmitting unit (200) for performing a designated operation for selectively transmitting the purpose-defined second radio signal through the user's terminal. 164, information storage unit 166, seed storage unit 168, code generation unit 170, PIN authentication unit 172, terminal authentication unit 174, communication processing unit 176 , A sending control unit 178, a seed determining unit 180, and a signal control unit 182 may be provided.

Meanwhile, according to an embodiment of the present invention, the second wireless module 140 may include a PIN storage area for storing PIN authentication information and an authentication information storage area for storing unique authentication information for authenticating a terminal (or program) that is a valid communication target. Check whether the valid PIN authentication information is registered in the memory unit 155 and the PIN storage area when communicating with the terminal. If the PIN authentication information is not registered, the PIN authentication information is registered from the terminal. If the PIN registration unit 160 is stored in the storage area and the PIN authentication information is registered in the PIN storage area when communicating with the terminal, check whether valid unique authentication information is registered in the authentication information storage area, and the unique authentication information is not registered. If not, the PIN authentication unit 172 for performing a PIN authentication procedure for the terminal using the PIN authentication information registered in the PIN storage area, and the unique authentication information The authentication information registration unit 162 receives the unique authentication information from the PIN-authenticated terminal and registers the authentication information storage area when the PIN is authenticated and the terminal is connected to the terminal in the state where the unique authentication information is registered. A terminal authentication unit 174 for authenticating the validity of a terminal (or a program mounted in the terminal) connected using the unique authentication information, and a communication processing unit 176 for communicating with the terminal authenticated through the unique authentication information. Can be configured.

Here, the second wireless module 140 may communicate with the terminal of the user through a bidirectional short range wireless communication connected by pairing with the terminal of the user according to a specified pairing procedure, and the bidirectional short range wireless communication is based on Bluetooth pairing based Bluetooth. May include communication.

According to the exemplary embodiment of the present invention, when the bidirectional short-range wireless communication is connected with the designated user terminal according to the designated pairing procedure, the PIN registration unit 160 performs a PIN authentication procedure on the PIN storage area set in the memory unit 155. It is possible to check whether valid PIN authentication information for performing is registered. If valid PIN authentication information is not registered in the PIN storage area, the PIN registration unit 160 receives PIN authentication information from the terminal through a communication connection with the terminal. Can be received and stored in the PIN storage area. Preferably, the PIN authentication information may be encrypted and stored in the PIN storage area.

According to the embodiment of the present invention, the PIN registration unit 160 may limit the communication connection for registering the PIN authentication information to Bluetooth-based short-range communication. Alternatively, when a different initial PIN is included in each high pass terminal 100 (eg, described in the manual) in the package of the high pass terminal 100, PIN authentication information may be registered through Bluetooth-based short-range communication.

According to the exemplary embodiment of the present invention, the PIN authentication unit 172 is configured to store the authentication information storage area set in the memory unit 155 when valid PIN authentication information is registered in the PIN storage area when communicating with the designated terminal. It is possible to check whether unique authentication information for uniquely identifying and authenticating a valid terminal (or a program mounted on the terminal) is registered.

If valid unique authentication information is not registered in the authentication information storage area, the PIN authentication unit 172 receives PIN information from the terminal through a communication connection with the terminal, and PIN authentication registered in the PIN storage area. PIN authentication procedure for the terminal can be performed using the information.

When the PIN authentication is confirmed through the PIN authentication unit 172 without valid unique authentication information registered in the authentication information storage area, the authentication information registration unit 162 authenticates the PIN through a communication connection with the terminal. The terminal receives unique authentication information for uniquely identifying and authenticating the PIN-authenticated terminal (or a program mounted in the PIN-authenticated terminal) from the terminal, and stores it in the authentication information storage area. Preferably, the unique authentication information may be encrypted and stored in the authentication information storage area.

According to the embodiment of the present invention, the unique authentication information registered in the authentication information storage area is a terminal identification value for uniquely identifying the terminal, and uniquely identifying a program mounted on the terminal and communicating with the second wireless module 140. App identification value, and may include at least one or a combination of two or more of the key value exchanged between the terminal (or program) and the second wireless module 140.

According to the embodiment of the present invention, when valid unique authentication information is registered in the authentication information storage area and is connected with a terminal, the terminal (or a program mounted on the terminal) is uniquely identified from the communication-connected terminal and authenticated. Receive the unique authentication information, and by authenticating the provided unique authentication information through the unique authentication information registered in the authentication information storage area can be authenticated the validity of the communication terminal (or a program mounted on the terminal).

Here, the unique authentication information received for the validity authentication is a terminal identification value for uniquely identifying the terminal, an app identification value for uniquely identifying a program mounted on the terminal and communicating with the second wireless module 140, the terminal ( Or a key value exchanged between the program and the second wireless module 140, and an authentication value generated using one or more of the above values. The terminal authentication unit 174 authenticates by comparing the value included in the received unique authentication information with the value stored in the authentication information storage area, or generated through the terminal (or program) to the received unique authentication information. When the authentication value is included, a verification value may be generated using a value stored in the authentication information storage area to authenticate the received authentication value.

When the communication terminal (or terminal (or program)) is authenticated through the unique authentication information stored in the authentication information storage area, the communication processing unit 176 connects various types of information or data with the terminal through a Bluetooth-based short-range communication connection. Can transmit and receive. Hereinafter, even if not mentioned otherwise, communication between the second wireless module 140 and the terminal may be performed through the communication processor 176.

According to the embodiment of the present invention, when the Bluetooth-based short-range communication connected terminal requests the addition or update of the unique authentication information, the PIN authentication unit 172 communicates with the terminal to add or update the unique authentication information. The PIN authentication procedure may be performed, and the authentication information registration unit 162 receives or receives unique authentication information from the PIN authenticated terminal and adds or updates the authentication information storage area when the PIN authentication is successful through the PIN authentication procedure. can do. For example, the PIN authentication process may be performed only when registering, adding, or updating unique authentication information. When a plurality of unique authentication information is registered in the authentication information storage area, the terminal authentication unit 174 One terminal (or terminal (or program)) of the plurality of terminals may be authenticated using the plurality of unique authentication information.

Meanwhile, according to another exemplary embodiment of the present invention, the second wireless module 140 uses a basic memory area for storing a data set for transmitting a basic second wireless signal and a second wireless device defined through an authenticated terminal. A memory unit 155 having an application-defined memory area for storing a data set for transmitting a signal, and an information storage unit 166 for storing unique information to be transmitted through the second default radio signal in the basic memory area. And a code generation unit 170 for dynamically generating a one-time code to be transmitted through the second basic radio signal, and a second radio including unique information and one-time code to be transmitted through the second basic radio signal. A signal transmitter 164 for transmitting a signal, and generating a seed storage unit 168 for storing one or more fixed seed values for generating the disposable code; Is one or more of the at least one seed crystal to determine the dynamic seed value unit 180 can be configured to further comprise.

The code generation unit 170 dynamically generates a disposable code to be transmitted through the second wireless signal using a designated code generation algorithm, preferably at least one fixed seed stored in a basic memory area of the memory unit 155. A value and at least one dynamic seed value determined by the seed determination unit 180 may be substituted into a designated code generation algorithm to dynamically generate a disposable code to be transmitted through the second radio signal.

The signal transmitter 164 checks the unique information stored in the basic setting memory area of the memory unit 155, and after confirming the disposable code dynamically generated by the code generator 170, the RF processor 150. ) May be processed so that the default second wireless signal including the unique information and the disposable code is transmitted. Preferably, the signal transmitter 164 may control the second radio signal to be transmitted more than the specified number of times (or periodically).

Meanwhile, referring to FIG. 1, the signal controller 182 of the second wireless module 140 may allow the second wireless signal to reach a predetermined distance outside a vehicle outside the front glass of the vehicle or beyond the side of the vehicle. 2 It can be controlled to amplify and transmit the signal strength of the radio signal.

According to the exemplary embodiment of the present invention, the signal controller 182 checks whether a first radio signal is transmitted in cooperation with the first radio module 115, and the first radio signal through the first radio module 115. When is transmitted may be controlled to pause the transmission of the second radio signal. For example, when the second radio signal (= BLE signal) is not used for a toll gate fee that replaces the high pass and is only used for parking, fueling, or vehicle tracking, while the high pass payment is processed through the first radio signal, Transmission can be paused.

According to another exemplary embodiment of the present invention, the signal controller 182 checks whether a first radio signal is transmitted in cooperation with the first radio module 115, and transmits a first radio through the first radio module 115. When a signal is transmitted, the signal strength of the second radio signal may be amplified and transmitted by a predetermined ratio or more. For example, when the second radio signal (= BLE signal) is used for a toll gate fee replacing the high pass, or used to provide a separate toll gate related service in addition to the toll gate fee, the signal strength of the first radio signal is higher than the signal strength of the first radio signal. Can be amplified highly.

Meanwhile, referring to FIG. 1, the second wireless module 140 provides usage definition information for selectively transmitting a usage-defined second wireless signal through the second wireless module 140 from a terminal that is effectively connected to the communication. It may be configured to include a communication processing unit 176 to receive and a transmission control unit 178 for controlling to transmit the use definition second radio signal corresponding to the use definition information.

According to the exemplary embodiment of the present invention, the communication processing unit 176 communicates with the terminal 300 authenticated through the unique authentication information when valid communication is connected with the terminal 300 through at least one of the Bluetooth-based short-range communication. When connected), it is possible to receive the use definition information for controlling to selectively transmit the use-defined second radio signal through the second wireless module 140 from the terminal effectively connected. Preferably, the use definition information may include unique information to be included in the use definition second radio signal, a seed value for generating a disposable code to be included in the use definition second radio signal (eg, one or more fixed seed values and / or at least one dynamic value). Seed value), and a combination of at least one or more than one protocol structure of the usage defined second radio signal.

According to a first embodiment of transmitting a second radio signal according to the use definition information of the present invention, the second radio module 140 stores information for storing unique information to be transmitted through the use definition second radio signal. And a signal transmitter 164 for transmitting a second radio signal including the unique information.

The information storage unit 166 may store the unique information included in the application definition information in the application definition memory area of the memory unit 155 under the control of the transmission control unit 178. ) Identifies the unique information stored in the definition memory area of the memory unit 155 under the control of the transmission control unit 255 and includes the unique information through the RF processing unit 150. The signal can be processed to be sent out. Preferably, the signal transmitter 164 may control the second radio signal to be transmitted more than the specified number of times (or periodically).

According to a second embodiment of transmitting a second radio signal according to the use definition information of the present invention, the second radio module 140, a code for dynamically generating a disposable code to be transmitted through the use definition second radio signal A seed storage unit having a generator 170 and a signal transmitter 164 for transmitting a second wireless signal including the generated disposable code, and storing one or more fixed seed values for generating the disposable code. 168 and at least one of the seed determination unit 180 for determining at least one dynamic seed value for generating the disposable code.

The seed storage unit 168 may store a fixed seed value of the seed values included in the application definition information under the control of the transmission control unit 178 (but may include a dynamic seed value according to an implementation method). 155) can be stored in the usage definition memory area.

The seed determiner 180 may generate at least one dynamic seed value (eg, a time value, a random number, or dynamic seed value included in usage definition information) at the time of generating the disposable code under the control of the transmission controller 178. Etc.).

The code generation unit 170 may dynamically generate a single-use code to be transmitted through the use-defined second wireless signal using a code generation algorithm specified by the control of the transmission control unit 178. According to an exemplary embodiment of the present invention, the code generator 170 may include one or more fixed seed values stored in the application-defined memory area of the memory unit 155 and at least one dynamic seed determined by the seed determiner 180. By assigning a value to a designated code generation algorithm, a single-use code to be transmitted through the use-defined second radio signal may be dynamically generated.

The signal transmitter 164 checks the disposable code dynamically generated by the code generator 170 under the control of the transmitter controller 178, and includes the disposable code through the RF processor 150. Usage Definition A second radio signal can be processed to be sent. Preferably, the signal transmitter 164 may control the second radio signal to be transmitted more than the specified number of times (or periodically).

According to a third embodiment of transmitting a second radio signal according to the use definition information of the present invention, the second radio module 140 stores information storing unique information to be transmitted through the use definition second radio signal. A unit 166, a code generation unit 170 for dynamically generating a one-time code to be transmitted through the use-defined second radio signal, and a signal transmitter for transmitting a second radio signal including the unique information and the one-time code 164, a seed storage unit 168 for storing one or more fixed seed values for generating the disposable code, and a seed determination unit 180 for determining at least one dynamic seed value for generating the disposable code. It may be configured with one or more of).

The code generation unit 170 dynamically generates a disposable code to be transmitted through the use-defined second wireless signal using a code generation algorithm specified by the control of the transmission control unit 178, and preferably, the memory unit 155 One or more fixed seed values stored in the application definition memory area and at least one dynamic seed value determined by the seed determination unit 180 are transmitted to the application defined second radio signal by substituting the specified code generation algorithm. Code can be generated dynamically.

The signal transmitter 164 checks the unique information stored in the application defined memory area of the memory unit 155 under the control of the transmitter control unit 178 and dynamically generates the disposable information through the code generation unit 170. After confirming the code, the RF processor 150 processes the use definition second radio signal including the unique information and the disposable code to be transmitted. Preferably, the signal transmitter 164 may control the second radio signal to be transmitted more than the specified number of times (or periodically).

According to the exemplary embodiment of the present invention, the transmitting control unit 178 is capable of performing Bluetooth-based short-range communication with the terminal while transmitting the use-defined second wireless signal (for example, the user carries the terminal and gets off the vehicle and the Bluetooth Or when the Bluetooth function of the terminal is released. If the Bluetooth-based short-range communication is impossible, the transmission control unit 178 may control to transmit the default second wireless signal. On the other hand, when the Bluetooth-based short-range communication is possible while transmitting the use-defined second radio signal, the transmission control unit 178 may control to transmit the use-defined second radio signal.

According to the exemplary embodiment of the present invention, the communication processor 176 checks whether the basic second radio signal is being transmitted or whether the usage-defined second radio signal is being transmitted under the control of the transmission control unit 178. The signal transmission information corresponding to the state of transmitting one of the basic set second wireless signal and the use defined second wireless signal may be configured and provided to a terminal to which Bluetooth-based short-range communication is connected.

2 is a diagram illustrating a process of transmitting a first radio signal and a second radio signal through an adaptive high pass terminal according to an exemplary embodiment of the present invention.

In more detail, FIG. 2 illustrates a timing point at which the first wireless signal is transmitted in the adaptive high pass terminal 100 having a function of transmitting a first radio signal and a function of transmitting a second radio signal (BLE). When the time point at which the radio signal is transmitted is different, for example, the first radio signal is used as a signal for high pass payment, and the second radio signal is other than the high pass payment (eg, parking, fueling, vehicle tracking, etc.). In the case of using, the process of transmitting the first radio signal and the second radio signal, and those skilled in the art to which the present invention pertains, refer to and / or modify the present invention. By using the adaptive high-pass terminal 100 to infer various implementation methods (for example, some steps are omitted, or the order is changed) for the process of transmitting the first radio signal and the second radio signal. It should be understood that the present invention includes all implementation methods inferred, and the technical features are not limited only to the implementation method shown in FIG.

Referring to FIG. 2, when the vehicle power supply is confirmed from the vehicle equipped with the adaptive high pass terminal 100 in the adaptive high pass terminal 100 (200), the vehicle power is supplied to the adaptive high pass terminal 100. In step 205, the IC chip of the card and the adaptive high pass terminal 100 in contact with each other are converted into a power source suitable for the first wireless module 115 and the second wireless module 140, respectively.

In addition, when the IC chip of the high pass card contacts the card reader unit 105 of the adaptive high pass terminal 100 (210), the adaptive high pass terminal 100 is the first for the high pass payment function; Wait for transmission of the radio signal (215).

In addition, the adaptive high pass terminal 100 initiates the transmission of the second radio signal for other functions (eg, parking, fueling, vehicle tracking, etc.) except for the high pass payment function (220).

Then, when the vehicle equipped with the adaptive high pass terminal 100 enters a high pass section (or toll gate section), the adaptive high pass terminal 100 transmits a first wireless signal for high pass payment. Check (225).

If the transmission of the first radio signal for the high pass payment is necessary, the adaptive high pass terminal 100 suspends transmission of the second radio signal (230), and the first terminal for the high pass payment is performed. 1 Transmission of the radio signal is started (235).

Thereafter, when the vehicle equipped with the adaptive high pass terminal 100 enters the high pass section (or the toll gate section), the high pass terminal 100 stops transmitting the first radio signal for the high pass payment. Check (240).

When the transmission of the first radio signal for the high pass payment is confirmed, the adaptive high pass terminal 100 resumes transmission of the second radio signal (245).

3 is a diagram illustrating a process of transmitting a first radio signal and a second radio signal through an adaptive high pass terminal according to another exemplary embodiment of the present invention.

In more detail, FIG. 3 illustrates a time point at which the first wireless signal is transmitted and a second time at the adaptive high pass terminal 100 having a function of transmitting a first wireless signal and a function of transmitting a second wireless signal (BLE, etc.). When the transmission time point of the radio signal is the same, for example, when the first radio signal is used as a signal for high pass payment, the second radio signal may be used for various other purposes including high pass payment (eg, a high pass card). When used as a supplementary service that can be provided in a toll gate or a high pass section, such as an alternative payment when a balance is insufficient or payment of an unpaid fee, etc. It shows a process of transmitting by amplifying to increase the recognition rate, and those skilled in the art to which the present invention pertains, refer to and / or modify the present invention By way of example, various implementation methods (e.g., some steps may be omitted or the order may be changed) may be inferred. However, the present invention includes all the implementation methods inferred, The technical features are not limited only to the illustrated embodiment.

Referring to FIG. 3, through the process of FIG. 2, the vehicle power supply is confirmed from the vehicle equipped with the adaptive high pass terminal 100 in the adaptive high pass terminal 100, and the vehicle power is supplied to the adaptive high pass terminal 100. After the IC chip of the card contacting the high-pass terminal 100 and the power supply suitable for the first wireless module 115 and the second wireless module 140 provided in the adaptive high-pass terminal 100, respectively, After the IC chip of the high pass card contacts the card reader 105 of the adaptive high pass terminal 100 and waits for transmission of the first wireless signal for the high pass payment function, the adaptive high pass terminal The second wireless signal 100 may be used for various other purposes including a high pass payment (for example, an alternative payment when the balance of the high pass card is insufficient, an additional service that can be provided in a toll gate or a high pass section, such as payment of an unpaid fee, etc.). The transmission of is started (300).

Then, when the vehicle equipped with the adaptive high pass terminal 100 enters a high pass section (or toll gate section), the adaptive high pass terminal 100 transmits a first wireless signal for high pass payment. In operation 305, when transmission of the first radio signal for the high pass payment is started 310, it is determined whether the amplification transmission of the second radio signal is performed (315).

The amplification transmission of the second wireless signal may be determined in various ways including the high pass payment of the second wireless signal in the toll gate or the high pass section (e.g., alternative payment when the balance of the high pass card is insufficient, payment of unpaid fees, etc.). It may be necessary to be used as a toll gate or an additional service that can be provided in the high pass section, and may be necessary to increase the recognition rate of the second wireless signal in consideration of the moving speed of the vehicle (high pass section).

If the second radio signal is required to be transmitted and recognized in a high pass section in which the first radio signal is transmitted (alternative payment for lack of balance in the high pass settlement through the first radio signal), the adaptation The high pass terminal 100 amplifies and transmits the signal strength of the second radio signal by a predetermined ratio or more (320).

Then, when the vehicle equipped with the adaptive high pass terminal 100 enters the high pass section (or toll gate section), the adaptive high pass terminal 100 transmits the first radio signal for the high pass payment. Check whether to stop (325).

When the transmission of the first radio signal for the high pass payment is confirmed, the adaptive high pass terminal 100 decreases the signal strength of the second radio signal to the initial transmission start time and starts transmission again. (330).

4 is a diagram illustrating a PIN authentication or unique authentication information registration process according to an embodiment of the present invention.

In more detail, FIG. 4 illustrates the second wireless module 140 and the terminal (eg, Bluetooth-based short-range communication) when the communication connection between the second wireless module 140 and the terminal of the adaptive high-pass terminal 100 is performed. Or a program) to perform a PIN authentication process by interworking with each other, and to register a unique authentication information for replacing a terminal (or program) authentication, and a person having ordinary knowledge in the technical field to which the present invention belongs. Although various implementation methods (for example, some steps may be omitted or changed in order) may be inferred from the PIN authentication to the unique authentication information registration process by referring to FIG. 4 and / or modifications, the present invention may be inferred from the above description. It is made to include all the inferred implementation method, the technical features are not limited only to the implementation method shown in FIG.

Referring to FIG. 4, the second wireless module 140 of the adaptive high pass terminal 100 confirms a communication connection with the terminal through Bluetooth-based short-range communication while operating by receiving power of the vehicle (400). The terminal (or program) also checks the communication connection with the second wireless module 140 of the adaptive high pass terminal 100 through the Bluetooth-based short-range communication (400).

When the communication connection with the terminal (or program) is confirmed, the second wireless module 140 checks whether valid PIN authentication information is registered in the PIN storage area (405). If valid PIN authentication information is registered in the PIN storage area, the second wireless module 140 confirms PIN registration information identifying that valid PIN authentication information is registered in the PIN storage area by the terminal (or program). In operation 400, if the valid PIN authentication information is not registered in the PIN storage area, the terminal (or program) requests to register the PIN authentication information.

The terminal (or program) checks whether valid PIN authentication information is registered in the communication-connected second wireless module 140 (420), and if valid PIN authentication information is not registered in the second wireless module 140. If not, the registration PIN information is input (425), the PIN authentication information for authenticating the PIN information is configured (430), and provided to the second wireless module 140 connected to the communication (435). The second wireless module 140 receives the PIN authentication information from the terminal (or program) and stores the PIN authentication information in a designated PIN storage area (440).

If valid PIN authentication information is registered in the PIN storage area, the second wireless module 140 checks whether valid unique authentication information is registered in the designated authentication information storage area (445). If valid unique authentication information is registered in the authentication information storage area, the second wireless module 140 authenticates the terminal (or program) to identify that valid unique authentication information is registered in the authentication information storage area. If the registration information is provided (450) and valid unique authentication information is not registered in the authentication information storage area, the second wireless module 140 is PIN information for registration of the unique authentication information from the terminal (or program). Receiving the PIN authentication procedure is performed (470).

Meanwhile, if valid PIN authentication information is registered in the second wireless module 140, the terminal (or program) uniquely identifies and authenticates the terminal (or program) in the second wireless module 140. Check whether the information is registered (455).

If valid unique authentication information for the terminal (or program) is not registered in the second wireless module 140, the terminal (or program) receives PIN information for authentication (460) and the input PIN. Information is provided to the second wireless module 140 to request PIN authentication (465), and the second wireless module 140 receives the PIN information and performs a PIN authentication procedure (470).

If the PIN authentication fails, the second wireless module 140 provides a PIN authentication error to the terminal (or program), and the terminal (or program) receives and outputs the PIN authentication error (475). .

On the other hand, if the PIN authentication is successful, the second wireless module 140 requests unique authentication information for uniquely identifying and authenticating the terminal (or program) to the terminal (or program) (480), and the terminal (or The program) configures unique authentication information for uniquely identifying and authenticating the corresponding terminal (or program) (485), and provides the second wireless module 140 connected to the communication (490), and the second wireless module 140 ) Receives the unique authentication information and stores it in the designated authentication information storage area (495).

On the other hand, if valid unique authentication information is registered in the second wireless module 140, the second wireless module 140 performs a procedure for authenticating the validity of the communication terminal (or program) using the unique authentication information. Can be done.

5 is a diagram illustrating a process of authenticating a second wireless module of a terminal (or program) authentication or an adaptive high pass terminal according to an embodiment of the present invention.

In more detail, FIG. 5 illustrates a case where valid unique authentication information for a terminal (or program) is registered in the second wireless module 140 of the adaptive high pass terminal 100. While performing a process of authenticating a terminal (or program) connected to the module 140 in communication, the process of authenticating the second wireless module 140 by the terminal (or program) according to an embodiment of the present invention. Those skilled in the art can refer to and / or modify this drawing to modify the terminal (or program) authentication of the second wireless module 140 of the adaptive high-pass terminal 100. It is possible to infer an implementation method (e.g., an implementation method in which some steps are omitted or the order is changed), but the present invention includes all the implementation methods inferred above, and is shown in FIG. Only exemplary method is not limited that technical feature.

Referring to FIG. 5, when valid unique authentication information for a terminal (or program) is registered in the second wireless module 140 of the adaptive high pass terminal 100, the terminal (or program) is connected to a second communication device. The wireless module 140 provides unique authentication information for uniquely identifying and authenticating the corresponding terminal (or program) (500), and the second wireless module 140 receives the unique authentication information from the terminal (or program). Receive (505).

The second wireless module 140 authenticates the validity of the unique authentication information received from the terminal by using the unique authentication information registered in the authentication information storage area (510). If the validity of the unique authentication information is not authenticated, the second wireless module 140 provides an authentication result including an authentication error to the terminal (or program) (515), and the validity of the unique authentication information is authenticated. In step 515, the authentication result corresponding to the authentication success of the unique authentication information is provided to the terminal (or program). When the validity of the unique authentication information is authenticated, the second wireless module 140 may receive use definition information for transmitting a use definition second wireless signal from the authenticated terminal (or program).

The terminal (or program) receives and reads an authentication result of the unique authentication information (520). If the validity of the unique authentication information is not authenticated, the terminal (or program) outputs an authentication error (525).

On the other hand, when the validity of the unique authentication information is authenticated, the terminal (or program) may provide the use definition information for controlling to transmit the use-defined second wireless signal through the second wireless module 140.

According to the exemplary embodiment of the present invention, the second wireless module 140 and the terminal (or program) register the module authentication information for the second wireless module 140 or use the registered module authentication information for the second. A procedure for authenticating the wireless module 140 may be performed.

The terminal (or program) checks whether the module authentication information for the second wireless module 140 is stored in the designated storage area of the terminal (530). If the module authentication information for the second wireless module 140 is not stored, the terminal (or program) checks the module authentication information preset in the second wireless module 140 (535). It can be stored in the designated storage area (540). And / or the terminal (or program) may determine the module authentication information for the second wireless module 140 and provide it to the second wireless module 140 (535), the second wireless module 140 ) May receive and store the module authentication information (535), and the terminal (or program) stores the module authentication information provided to the second wireless module 140 in a designated storage area (540).

On the other hand, if the module authentication information for the second wireless module 140 is stored in the designated storage area of the terminal, the terminal (or program) requests the module authentication information to the second wireless module 140 (545). The second wireless module 140 checks the module authentication information (550) and provides it to the terminal (or program) (555).

The terminal (or program) authenticates the validity of the module authentication information received from the second wireless module 140 using the module authentication information stored in the designated storage area (560). If the validity of the module authentication information is not authenticated, the terminal (or program) outputs an authentication error (525).

On the other hand, if the validity of the module authentication information is authenticated, the terminal (or program) provides the authentication result of the module authentication information to the second wireless module 140 (565), and then the second wireless module 140 The use definition may provide use definition information for controlling to transmit the use definition second radio signal.

The second radio module 140 receives an authentication result of the module authentication information from the terminal (or program) (570), and then defines a use for transmitting a use definition second radio signal from the terminal (or program). Information can be received.

6 is a diagram illustrating a second radio signal transmission process through a second radio module of the adaptive high pass terminal according to the first embodiment of the present invention.

In more detail, FIG. 6 transmits a basic second wireless signal including unique information of the second wireless module 140 of the adaptive high-pass terminal 100, and uses definition information from an authenticated terminal (or program). Shows a process of selectively transmitting a use definition second radio signal corresponding to the use definition information when received, and a person skilled in the art to which the present invention pertains refers to FIG. 6 and / or Alternatively, it may be modified to infer various implementation methods (for example, some steps may be omitted or the order may be changed) for the second radio signal transmission process of the second radio module 140 of the adaptive high pass terminal 100. Although the present invention may be made, the present invention includes all the implementation methods inferred, and the technical features are not limited to the implementation method shown in FIG.

Referring to FIG. 6, when power is supplied from the vehicle to the second wireless module 140 of the adaptive high pass terminal 100, the second wireless module 140 checks the unique information stored in the basic setting memory area. In operation 600, a basic second wireless signal including the unique information is generated and transmitted.

The second wireless module 140 checks whether the definition information generated through the process shown in FIG. 7 is received from the terminal (or program) authenticated through the process shown in FIG. 5 (610). If the usage definition information is not received, the second wireless module 140 repeats the process of transmitting the basic second wireless signal more than a specified number of times or periodically.

When the definition information is received from the authenticated terminal (or program), the second wireless module 140 stores the value / information included in the definition information in the designated definition memory area (615). The application definition second radio signal including the unique information of the usage definition information and / or including the one-time code dynamically generated using the value included in the usage definition information is generated and transmitted (620).

The second wireless module 140 determines whether to stop transmitting the use-defined second wireless signal while transmitting the use-defined second wireless signal (625). If it is not determined that the transmission of the use-defined second radio signal is determined, the second radio module 140 repeats the process of transmitting the use-defined second radio signal more than a specified number of times or periodically.

On the other hand, when it is determined that the transmission of the use-defined second wireless signal is determined, the second wireless module 140 performs a process of transmitting the basic second wireless signal.

7 is a diagram illustrating a process of transmitting a second radio signal through a second radio module of the adaptive high pass terminal according to the second embodiment of the present invention.

In more detail, FIG. 7 selectively transmits a basic second wireless signal including a disposable code generated by the second wireless module 140 of the adaptive high pass terminal 100 according to a power supply state, When the use definition information is received from the terminal (or program), a process of selectively transmitting a use definition second radio signal corresponding to the use definition information is shown, and having ordinary skill in the art to which the present invention pertains. In this regard, various implementation methods (eg, some steps may be omitted) for the second radio signal transmission process of the second radio module 140 of the adaptive high pass terminal 100 by referring to and / or modifying the present invention. Or an implementation method in which the order is changed), but the present invention includes all implementation methods inferred from the above, and only the implementation method shown in FIG. The technical features are not limited.

Referring to FIG. 7, when operating power is supplied to the second wireless module 140 of the adaptive high pass terminal 100, the second wireless module 140 may store one or more fixed seed values stored in the basic memory area. After confirming (700) and determining at least one dynamic seed value for generating a one-time code (705), the one-time code is dynamically generated by assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm 710. If the one-time code is generated, the second wireless module 140 generates and transmits a basic second wireless signal including the one-time code (715).

The second wireless module 140 checks whether the usage definition information generated through the process illustrated in FIG. 9 is received from the terminal (or program) authenticated through the process illustrated in FIG. 5 (720). If the usage definition information is not received, the second wireless module 140 repeats the process of transmitting the basic second wireless signal more than a specified number of times or periodically.

Meanwhile, when the definition information is received from the authenticated terminal (or program), the second wireless module 140 stores the value / information included in the definition information in a designated definition memory area (725). Using the value included in the definition information and / or using the value included in the definition information to generate and transmit a use definition second radio signal including a dynamically generated disposable code (730).

The second wireless module 140 determines whether to stop transmitting the usage-defined second wireless signal while transmitting the usage-defined second wireless signal (735). If it is not determined that the transmission of the use-defined second radio signal is determined, the second radio module 140 repeats the process of transmitting the use-defined second radio signal more than a specified number of times or periodically.

On the other hand, when it is determined that the transmission of the use-defined second wireless signal is determined, the second wireless module 140 performs a process of transmitting the basic second wireless signal.

8 is a diagram illustrating a process of transmitting a second radio signal through a second radio module of the adaptive high pass terminal according to the third embodiment of the present invention.

In more detail, FIG. 8 illustrates a basic setting second including unique information of the second wireless module 140 of the adaptive high pass terminal 100 and including a one-time code generated through the second wireless module 140. The present invention relates to a process of selectively transmitting a second wireless signal corresponding to the usage definition information when transmitting the wireless signal and receiving the usage definition information from an authenticated terminal (or program). Those skilled in the art can refer to and / or modify this drawing to describe various implementation methods for the second radio signal transmission process of the second radio module 140 of the adaptive high pass terminal 100 ( For example, some steps may be omitted, or the order of implementation may be changed), but the present invention includes all the implementation methods inferred above, and is shown in FIG. Only the method is not limited that technical feature.

Referring to FIG. 8, when operation power is supplied to the second wireless module 140 of the adaptive high pass terminal 100, the second wireless module 140 checks the unique information stored in the basic memory area (see FIG. 8). 800). The second wireless module 140 checks one or more fixed seed values stored in the basic memory area (805), determines at least one dynamic seed value for generating the disposable code (810), and then designates a code generation algorithm. At least one fixed seed value and at least one dynamic seed value are substituted into the one-time code to be dynamically generated (815). If the one-time code is generated, the second wireless module 140 generates and transmits a basic second wireless signal including the one-time code (820).

The second wireless module 140 checks whether the usage definition information generated through the process shown in FIG. 9 is received from the terminal (or program) authenticated through the process shown in FIG. 5 (825). If the usage definition information is not received, the second wireless module 140 repeats the process of transmitting the basic second wireless signal more than a specified number of times or periodically.

Meanwhile, when the definition information is received from the authenticated terminal (or program), the second wireless module 140 stores the value / information included in the definition information in the designated definition memory area (830). The usage definition second wireless signal including the unique information of the usage definition information and / or using the value included in the usage definition information is dynamically generated (835).

The second wireless module 140 determines whether to stop transmitting the usage-defined second wireless signal while transmitting the usage-defined second wireless signal (840). If it is not determined that the transmission of the use-defined second radio signal is determined, the second radio module 140 repeats the process of transmitting the use-defined second radio signal more than a specified number of times or periodically.

On the other hand, when it is determined that the transmission of the use-defined second wireless signal is determined, the second wireless module 140 performs a process of transmitting the basic second wireless signal.

9 is a diagram illustrating a process of providing usage definition information to a second wireless module of an adaptive high pass terminal according to an exemplary embodiment of the present invention.

In more detail, in FIG. 9, the terminal (or program) authenticated through the process illustrated in FIG. 5 generates use definition information and provides the defined definition information to the second wireless module 140 of the adaptive high pass terminal 100. A process of allowing the second wireless module 140 to selectively transmit a use-defined second wireless signal as shown in FIGS. 6 to 8, which is common in the art to which the present invention pertains. Those skilled in the art may refer to and / or modify this drawing 9 to infer various methods of implementing the definition information providing process (for example, some steps may be omitted or the order may be changed). The present invention includes all the implementation methods inferred, and the technical features are not limited only to the implementation method shown in FIG.

Referring to FIG. 9, the terminal (or program) generates usage definition information for controlling the use definition second radio signal to be transmitted through the second radio module 140 of the adaptive high pass terminal 100 (900). ). The terminal (or program) may generate the definition information before being authenticated through the process shown in FIG. 5, and preferably, generate the usage definition information after authentication through the process shown in FIG. 5. can do. The use definition information may be generated by combining at least one or more pieces of information input through user manipulation and / or information received from a designated server (not shown), and preferably included in the use definition second radio signal. At least one of unique information, a seed value (eg, one or more fixed seed values and / or at least one dynamic seed value) for generating a disposable code to be included in the usage defined second radio signal, and a protocol structure of the usage defined second radio signal Or combinations of more than one stone.

When the definition information is generated, the terminal (or program) provides the definition information to the second wireless module 140 of the adaptive high-pass terminal 100 connected to the communication (905), the second wireless module 140 may selectively transmit a use definition second radio signal corresponding to the use definition information through the process illustrated in FIGS. 6 to 8.

On the other hand, after the terminal (or program) provides the definition information to the second radio module 140, the use definition second radio signal corresponding to the definition information through the second radio module 140 Check if the transmission (910).

According to the first signal transmission determination embodiment of the present invention, the terminal (or program) is basically set from the second wireless module 140 of the adaptive high pass terminal 100 through the second wireless module 140. Receives signal transmission information for determining whether to transmit a second radio signal or a usage definition second radio signal corresponding to the use definition information, and read the received signal transmission information to read the second radio module 140. ), It may be determined whether the use definition second radio signal corresponding to the use definition information is transmitting or the basic setting second radio signal is transmitting.

According to the second signal transmission determination embodiment of the present invention, the terminal (or program) is transmitted through the second wireless module 140 of the adaptive high-pass terminal 100 in conjunction with the Bluetooth module of the terminal and The second wireless signal received through the Bluetooth module (for example, the second wireless signal can be transmitted without pairing and can also be received by the Bluetooth module of the terminal) is checked, and the second wireless signal transmitted through the second wireless module 140 is checked. The second wireless module 140 may read the signal to determine whether the usage-defined second wireless signal corresponding to the usage definition information is being transmitted or whether the basic second wireless signal is being transmitted.

According to the third signal transmission determination embodiment of the present invention, the terminal (or program) may check whether the Bluetooth-based short-range communication with the second wireless module 140 is possible, and when the Bluetooth-based short-range communication is impossible, the adaptive high The second wireless module 140 of the pass terminal 100 may determine that the use definition second wireless signal corresponding to the use definition information has been stopped.

According to a fourth signal transmission determination embodiment of the present invention, the terminal (or program) may combine the first to third signal transmission determination embodiments with two or more second wireless modules of the adaptive high pass terminal 100. Through 140, it is possible to determine whether the basic second wireless signal is being transmitted (or discontinuing transmission of the usage-defined second wireless signal) or whether the usage-defined second wireless signal corresponding to the usage definition information is being transmitted. The present invention is not limited by this.

If it is determined that the use-defined second radio signal is being transmitted through the second radio module 140 of the adaptive high pass terminal 100 according to the first to fourth signal transmission determination embodiments, the terminal (or Program) outputs information corresponding to the use-defined second wireless signal transmission (915).

On the other hand, it is confirmed that transmission of the usage-defined second radio signal is stopped through the second radio module 140 of the adaptive high pass terminal 100 through the first to fourth signal transmission determination embodiments, or the basic If it is determined that the set second radio signal is being transmitted, the terminal (or program) outputs information corresponding to the interruption of the transmission of the use-defined second radio signal (or the transmission of the basic set second radio signal) (920).

100: high pass terminal 105: card reader unit
110: high pass module 115: first wireless module
120: first antenna portion 125: power supply
130: power conversion unit 135: second antenna unit
140: second wireless module 145: control unit
150: RF processing unit 155: memory unit
160: PIN register 162: Authentication information register
164: signal transmitter 166: information storage
168: Seed storage unit 170: Code generation unit
172: PIN authentication unit 174: terminal authentication unit
176: communication processing unit 178: transmission control unit
180: seed determination unit 182: signal control unit

Claims (32)

A power supply unit for receiving vehicle power, a power conversion unit for converting the vehicle power into one or more operating powers, and an operating power source converted for an IC chip and operating in contact with an IC chip of a Hi-Pass card. An operation designated through a card reader unit reading a first wireless signal and a first base station signal installed on a road of a designated road and a first wireless signal of a preset first radio frequency band operating through a power source converted to correspond to the first wireless signal; A first wireless module configured to perform a first wireless signal and an operating power corresponding to the first wireless signal, and a first antenna unit configured to transmit and receive a first wireless signal based on a specified operation of the first wireless module and a designated operating power source. It operates and interlocks with the IC chip of the high pass card through the card reader unit and interlocks with the roadside base station through the first wireless module. In the high pass terminal having a high pass module for performing the procedure,
It operates through a specified specific operating power source and is configured to transmit a preset second radio signal of a second radio frequency band different from the first radio frequency band, and selectively transmit a purpose-defined second radio signal through a user terminal. A second wireless module performing an operation; And
And a second antenna unit operating through the specific operation power source and transmitting a second radio signal based on a specified operation of the second radio module.
The method of claim 1, wherein the first wireless signal,
Adaptive high-pass terminal characterized in that it comprises a radio frequency signal for transmitting and receiving by the Dedicated Short-Range Communications (DSRC) method of the 5.9GHz band.
The method of claim 1, wherein the second wireless module,
The second radio signal of the second radio frequency band different from the first radio frequency band is transmitted so as not to interfere with the first radio signal without using the second radio signal defined by the user through the first radio signal. Adaptive high-pass terminal characterized in that performing a specified operation to selectively transmit so as not to interfere with.
The method of claim 3, wherein the second wireless module,
And adaptively oscillating and transmitting a second radio signal of a second radio frequency band in which frequency interference with the first radio frequency band is minimized among two or more radio frequency bands that can be transmitted.
The method of claim 1,
The second wireless module includes a BLE chip capable of transmitting a BLE (Bluetooth Low Energy) signal,
And the second radio signal of the second radio frequency band includes a BLE signal having a specified signal strength.
The method of claim 1, wherein the specific operating power source,
And a power source converted from the vehicle power source to amplify and transmit the second radio signal of the second radio frequency band to a specified signal intensity.
The method of claim 1, wherein the specific operating power source,
If the second wireless module is a BLE (Bluetooth Low Energy) module,
The voltage of the specific operating power supply conforms to the BLE standard, wherein the current of the specific operating power supply is an adaptive high-pass terminal, characterized in that it comprises a power converted by a certain ratio greater than the current of the BLE standard.
The method of claim 1,
The high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that faces the vehicle front direction,
The second antenna unit, the adaptive high-pass terminal, characterized in that disposed not to overlap with the first antenna unit on the basis of the vehicle front direction.
The method of claim 1,
The high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that faces the vehicle front direction,
The second antenna unit, the adaptive high-pass terminal, characterized in that it is disposed so as not to overlap with the first antenna unit on the basis of a predetermined angle upper direction of the vehicle front direction.
The method of claim 1,
The high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that is oriented at a predetermined angle in the upper direction of the vehicle front direction.
The second antenna unit, the adaptive high-pass terminal, characterized in that it is disposed so as not to overlap with the first antenna unit on the basis of a predetermined angle upper direction of the vehicle front direction.
The method of claim 1,
The high pass terminal is mounted on a designated portion inside the vehicle in a mounting form that is oriented at a predetermined angle in the upper direction of the vehicle front direction.
The second antenna unit, the adaptive high-pass terminal, characterized in that disposed not to overlap with the first antenna unit on the basis of the vehicle front direction.
The method of claim 10 or 11, wherein the mounting form,
Adaptive high-pass terminal, characterized in that comprises a vehicle front glass attachment form or a vehicle dashboard attachment form.
The method of claim 1, wherein the second wireless module,
A memory unit having a PIN storage area for storing PIN authentication information and an authentication information storage area for storing unique authentication information for authenticating a terminal (or program) which is a valid communication target;
A PIN registration unit for confirming that valid PIN authentication information is registered in a PIN storage area when communicating with the terminal, and receiving PIN authentication information from the terminal and storing the PIN authentication information in the PIN storage area if the PIN authentication information is not registered;
When PIN authentication information is registered in the PIN storage area when connecting with the terminal, check whether valid unique authentication information is registered in the authentication information storage area, and if the unique authentication information is not registered, PIN authentication information registered in the PIN storage area. PIN authentication unit for performing a PIN authentication procedure for the terminal using;
And an authentication information registration unit receiving unique authentication information from the PIN authenticated terminal and registering in the authentication information storage area when the PIN is authenticated without the unique authentication information registered.
The method of claim 13, wherein the second wireless module,
Adaptive high-pass terminal, characterized in that for communicating with the terminal of the user via a two-way short-range wireless communication connected to the terminal of the user according to a specified pairing procedure.
The method of claim 14, wherein the bidirectional short range wireless communication,
An adaptive high pass terminal comprising Bluetooth communication based on Bluetooth pairing.
The method of claim 13,
A terminal authentication unit for authenticating a validity of a terminal (or a program mounted on the terminal) by using the unique authentication information when communicating with the terminal while the unique authentication information is registered; And
Adaptive high-pass terminal comprising a; communication processing unit for communicating with the terminal authenticated through the unique authentication information.
The method of claim 13,
The PIN authentication unit performs a PIN authentication procedure for adding or updating the unique authentication information,
And the authentication information registration unit receives unique authentication information from the PIN-authenticated terminal and adds or updates the authentication information storage area to the authentication information storage area.
The method of claim 1, wherein the second wireless module,
A memory unit having a basic setting memory area for storing a data set for transmitting a second set of wireless signals and a use-defined memory area for storing a data set for transmitting a defined second wireless signal through an authenticated terminal; Adaptive high pass terminal, characterized in that comprises a.
The method of claim 18, wherein the second wireless module,
An information storage unit for storing the unique information to be transmitted through the second basic radio signal in the basic memory area; And
And a signal transmitter for transmitting a second radio signal including the unique information of the basic memory area.
The method of claim 18, wherein the second wireless module,
A seed storage unit for storing one or more fixed seed values for generating a disposable code to be transmitted through a second basic radio signal in the basic memory area;
A seed determination unit to determine at least one dynamic seed value for generating the disposable code;
A code generator for dynamically generating a disposable code by assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm; And
Adaptive high-pass terminal characterized in that it comprises a; signal transmission unit for transmitting a second wireless signal including the disposable code.
The method of claim 18, wherein the second wireless module,
An information storage unit for storing the unique information to be transmitted through the second basic radio signal in the basic memory area;
A seed storage unit for storing one or more fixed seed values for generating a disposable code to be transmitted through a second basic radio signal in the basic memory area;
A seed determination unit to determine at least one dynamic seed value for generating the disposable code;
A code generator for dynamically generating a disposable code by assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm; And
And a signal transmitting unit configured to transmit a second radio signal including the unique information of the basic memory area and the disposable code.
The method of claim 1, wherein the second wireless module,
And a signal controller configured to amplify and transmit the signal strength of the second wireless signal so that the second wireless signal can be reached to a predetermined distance outside the vehicle beyond the front glass of the vehicle or beyond the side of the vehicle. Adaptive high pass terminal.
The method of claim 1, wherein the second wireless module,
A signal control unit which checks whether a first radio signal is transmitted in association with the first radio module, and controls to pause transmission of the second radio signal when the first radio signal is transmitted through the first radio module; Adaptive high pass terminal, characterized in that comprises a.
The method of claim 1, wherein the second wireless module,
Check whether the first radio signal is transmitted in cooperation with the first radio module, and when the first radio signal is transmitted through the first radio module, amplify and transmit the signal strength of the second radio signal by a predetermined ratio or more. An adaptive high pass terminal comprising a signal controller for controlling.
The method of claim 1, wherein the second wireless module,
A communication processor configured to receive usage definition information for selectively transmitting a usage-defined second wireless signal through a second wireless module, which is effectively connected to the terminal; And
And an outgoing control unit configured to control outgoing use definition second radio signals corresponding to the use definition information.
The method of claim 25, wherein the use definition information,
Use definition unique information to be included in the second radio signal,
Use definition Seed value for generating a one-time code to be included in the second radio signal,
Usage definition An adaptive high pass terminal comprising at least one of protocol structures of a second radio signal.
The method of claim 25, wherein the second wireless module,
An information storage unit for storing the unique information included in the definition information in the definition memory area; And
And a signal transmitter for transmitting a second radio signal including the unique information of the application-defined memory region.
The method of claim 25, wherein the second wireless module,
A seed storage unit for storing at least one fixed seed value included in the usage definition information in the usage definition memory area;
A seed determination unit to determine at least one dynamic seed value for generating the disposable code;
A code generator for dynamically generating a disposable code by assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm; And
Adaptive high-pass terminal characterized in that it comprises a; signal transmission unit for transmitting a second wireless signal including the disposable code.
The method of claim 25, wherein the second wireless module,
An information storage unit for storing the unique information included in the definition information in the definition memory area;
A seed storage unit for storing at least one fixed seed value included in the usage definition information in the usage definition memory area;
A seed determination unit to determine at least one dynamic seed value for generating the disposable code;
A code generator for dynamically generating a disposable code by assigning at least one fixed seed value and at least one dynamic seed value to a designated code generation algorithm; And
And a signal transmitting unit configured to transmit a second radio signal including the unique information of the use-defined memory area and the disposable code.
The method of claim 25, wherein the delivery control unit,
Determining whether a bidirectional short-range wireless communication with the terminal is possible while transmitting the use definition second wireless signal,
Adaptive high-pass terminal, characterized in that for controlling the two-way short-range wireless communication to transmit the default second radio signal.
The method of claim 25, wherein the delivery control unit,
Determining whether a bidirectional short-range wireless communication with the terminal is possible while transmitting the use definition second wireless signal,
Adaptive high-pass terminal, characterized in that for controlling the two-way short-range wireless communication to transmit the use-defined second radio signal.
The method of claim 25, wherein the communication processing unit,
Adaptive high-pass terminal, characterized in that to provide the terminal with the signal transmission information corresponding to the state of transmitting any one of the second radio signal and the use-defined second wireless signal.

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