KR20140036564A - Method and apparatus for defending relay attack with respect to passive keyless entry smart key using sound - Google Patents

Abstract

Disclosed are a method and an apparatus for defending a relay attack of a passive keyless entry smart key using sound. An authentication method for authenticating a base station in a transponder comprises the steps of: receiving an electromagnetic wave signal and a signal sound from a base station; determining the validity of the electromagnetic wave signal using at least one among the volume of the signal sound, whether the signal sound is received or not and a difference value between the reception time of the electromagnetic wave signal and the reception time of the signal sound; and transmitting a response signal including a response to the base station when the electromagnetic wave signal is valid. The base station determines the validity of the response and executes a predetermined operation when the response is valid. [Reference numerals] (310) Base station; (320) Transponder; (331) Transmit signal sound and an electromagnetic wave signal including a command; (332) Determine the effectiveness of a command received using signal sound and transmit a response signal including response when the command is effective; (333) Execute a predetermined operation when the response is effective by determining the effectiveness of the received response; (AA) End

Description

TECHNICAL AND APPARATUS FOR DEFENDING RELAY ATTACK WITH RESPECT TO PASSIVE KEYLESS ENTRY SMART KEY USING SOUND}

Embodiments of the present invention relate to a method and apparatus for defending a relay attack of a passive keyless entry smart key using sound.

The vehicle is constantly developing new systems for the driver's convenience and safety, especially as the customer's needs are constantly raised for the inconvenience of entering and starting the vehicle most frequently. In order to make it convenient to use, a smart key system has been introduced to perform the vehicle in and start operation comfortably while integrating the functions of the existing key and the remote key, and various studies are being conducted. For example, Korean Patent Laid-Open No. 10-2010-0049902 discloses a smart key system that effectively divides an operation region.

In the present specification, a method and apparatus for more secure remote control of a vehicle, a specific apparatus, and the like are provided.

The present invention provides a method and apparatus for more safely remotely controlling a vehicle or a specific device by using a sound signal such as a signal sound to check a distance between remote devices.

A method of authenticating a base station in a transponder, the method comprising: receiving a radio signal and a signal from the base station, a difference value between a reception time of the signal sound and a reception time of the radio signal, a magnitude of the signal sound, and reception of the signal sound Determining whether the radio signal is valid using at least one of whether the radio signal is valid, and if it is determined that the radio signal is valid, transmitting a response signal including a response to the base station. The validity of the response is determined, and if the response is valid, an authentication method is provided, wherein a predetermined operation is performed at the base station.

According to one side, the step of determining whether the radio signal is valid, when the difference value is less than or equal to the preset valid value based on the effective distance between the transponder and the base station, characterized in that the radio signal is determined to be valid. You can do

According to another aspect, the determining whether the radio signal is valid, calculating the distance between the transponder and the base station based on the difference value and the calculated distance between the transponder and the base station If less than the effective distance, it may be characterized in that it is determined that the radio signal is valid.

According to another aspect, the determining of the validity of the radio signal is that the radio signal is valid when the loudness is greater than or equal to a preset sound volume based on the effective distance between the transponder and the base station. It may be characterized by judging.

According to another aspect, determining whether the radio signal is valid, when the signal tone is received, it may be determined that the radio signal is valid, the signal tone is the transponder and the base station in the base station The transmission intensity may be preset based on the effective distance of the liver.

According to another aspect, the radio signal may include an identification number of the device including the base station, the transmission time of the radio signal in the base station and the identification number of the signal tone, wherein the signal tone is It may be characterized in that it is generated to be encoded to include at least an identification number.

According to another aspect, the authentication method may further include determining whether the signal tone is valid by comparing the identification number of the signal tone included in the radio signal with the identification number extracted from the signal tone.

According to another aspect, the authentication method may further include determining whether the radio signal is valid based on a difference between a reception time of the radio signal and a transmission time of the radio signal.

According to another aspect, the radio signal may further include a Message Authentication Code (MAC) calculated using a key shared in advance between the transponder and the base station.

A method of operating a base station, the method comprising: transmitting a radio signal and a signal sound to a transponder, receiving a response signal received from the transponder based on the radio signal and the signal sound, and a response included in the response signal If it is determined to be valid, performing a predetermined operation, wherein the transponder includes at least one of a difference between a reception time of the signal tone and a reception time of the radio signal, a magnitude of the signal tone, and whether the signal tone is received or not; The validity of the radio wave signal is determined by using, and the response signal is transmitted when the radio signal is determined to be valid by the transponder.

A transponder apparatus for authenticating a base station, comprising: a receiver for receiving a radio signal and a signal sound from the base station, a difference value between a reception time of the signal sound and a reception time of the radio signal, a magnitude of the signal sound, and whether the signal sound is received or not A validity determination unit that determines whether the radio signal is valid using at least one of; and a response signal transmitter that transmits a response signal including a response to the base station when it is determined that the radio signal is valid; The validity of the response is determined at the base station, and if the response is valid, a transponder device is provided, wherein a predetermined operation is performed at the base station.

A base station apparatus, comprising: a transmitter for transmitting a radio signal and a signal tone to a transponder, a response signal receiver for receiving a response signal generated from the transponder based on the radio signal and the signal tone and a response included in the response signal If it is determined that the validity, and includes an operation performing unit for performing a predetermined operation, the difference between the reception time of the signal tone and the reception time of the radio signal in the transponder, the volume of the signal tone and whether or not the reception of the signal tone It is determined whether the radio signal is valid using at least one, and the response signal is provided when the radio signal is determined to be valid by the transponder.

A computer readable storage medium comprising instructions for a computer system to authenticate a base station, the instructions comprising: receiving a radio signal and a beep from the base station, receiving time of the beep and receiving the radio signal; Determining whether the radio signal is valid using at least one of a difference value between time, the volume of the signal, and whether the signal is received, and when the radio signal is determined to be valid, a response is included in the base station. And transmitting a response signal, wherein the validity of the response is determined at the base station, and if the response is valid, a predetermined operation is performed at the base station. Computer readable storage media It is provided.

A computer readable storage medium comprising instructions for performing a predetermined operation by a computer system, the instructions comprising: transmitting a radio signal and a beep sound to a transponder, based on the radio signal and the beep sound. Receiving a response signal received from a fender and performing a predetermined operation when it is determined that the response included in the response signal is valid, wherein the transponder receives a reception time of the tones and the radio signal The validity of the radio signal is determined using at least one of a difference between reception times, the volume of the signal, and whether the signal is received, and the response signal is determined to be valid by the transponder. And the computer system according to an operating method characterized in that it is transmitted to. For example, a computer readable storage medium is provided.

By using a sound signal such as a signal sound to check the distance between the remote devices it is possible to remotely control the vehicle or a specific device more safely.

1 is a diagram illustrating a communication process between a base station and a transponder in the prior art.
2 is a view for explaining a relay attack in the prior art.
3 is a diagram illustrating a communication process between a base station and a transponder according to an embodiment of the present invention.
4 is a flowchart illustrating a method of determining the validity of a command according to an embodiment of the present invention.
5 is a flowchart illustrating an authentication method according to an embodiment of the present invention.
6 is a flowchart illustrating an operating method according to an embodiment of the present invention.
FIG. 7 is a block diagram illustrating an internal configuration of a base station and a transponder according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1. Background ( background )

1 is a diagram illustrating a communication process between a base station and a transponder in the prior art. 1 shows a base station 110 and a transponder 120.

The base station 110 may be included in a device (eg, a vehicle) that performs a specific operation (eg, an unlock), and periodically transmits a command by using a low frequency (LF) low power signal. It may wait to receive a response from a valid device within range. That is, in step 131, the base station 110 may transmit a command to the transponder 120. In this case, the transponder 120 may receive such a command using an antenna.

Transponder 120 may use dual frequencies. For example, transponder 120 receives data using an LF (e.g., 125 kHz) signal, and data using an Ultra High Frequency (UHF) signal, such as 315, 433, 868 or 915 MHz. Can be transmitted. That is, the transponder 120 may receive a command from the base station 110 using the LF signal, and simultaneously use the UHF signal to respond to the LF signal or to transmit a user command to the base station 110. have. That is, in steps 132 and 133 the transponder 120 determines the validity of the received command and, if the command is valid, transmits a response to the command to the base station 110 as in step 134. Can be. This response may be sent to the base station 110 as encrypted data through the UHF transmitter of the transponder 120.

When base station 110 receives a response from transponder 120, base station 110 may determine the validity of the received response as in step 135. At this time, if the response is valid, the base station 110 may execute a predetermined operation as in step 137. For example, the predetermined operation may include an operation of operating a switch, such as an operation for unlocking a vehicle.

The bidirectional communication distance between the base station 110 and the transponder 120 may generally be less than about 3 meters, due to the non-propagating nature of the LF signal, and the transponder 120 may always remain in receive mode except in special cases. have.

In addition, the transponder 120 may include a user interface (eg, a pushbutton) for user input, and may be unidirectional and long to transmit user input information input through the user interface to the base station 110. UHF signals can be used to support distance.

2 is a view for explaining a relay attack in the prior art.

The first repeater 210 receives a signal including a command transmitted by the base station 110 near the base station 110, amplifies the received signal, and retransmits the received signal.

The second repeater 220 transmits the signal retransmitted by the first repeater 210 to the transponder 120 near the transponder 120.

The transponder 120 transmits the signal including the response to the base station 110 because the transponder 120 received the signal containing the valid command.

At this time, the second repeater 220 near the transponder 120 receives a signal containing a response and then amplifies and retransmits the received signal.

Since the base station 110 receives a signal including a valid response from the transponder 120, the base station 110 performs a preset operation.

That is, even if the distance between the vehicle and the smart key is far, there is a problem that the third party can unlock the vehicle through the relay attack.

2. According to the present invention Example

Hereinafter, embodiments of the present invention will be described a method and apparatus that can solve the problems caused by the above-described relay attack using a sound, such as a beep.

3 is a diagram illustrating a communication process between a base station and a transponder according to an embodiment of the present invention.

First, time synchronization may be performed between the base station 310 and the transponder 320 according to the present embodiment. For example, a time synchronization protocol may be automatically performed whenever a user rides in a vehicle including the base station 310 while carrying the transponder 320. In addition, a key to be used for calculating a message authentication code (MAC) may be shared between the base station 310 and the transponder 320 in advance. Here, the MAC and the key of the MAC can be selectively used, and need not be included as an essential component for the practice of the present invention.

In step 331, the base station 310 transmits a radio signal and a tone. Here, the radio signal may include a command including [car identification number, current time, identification number and random identification of a randomly generated beep tone], and the beep signal is transmitted for distance measurement. Can be. Such a signal sound may be transmitted using a speaker that may be included in the base station 310 or a speaker of a device including the base station 310, and may be transmitted at a frequency of a band that is inaudible to humans, such as ultrasound. .

At this time, the transponder 320 may be generally implemented in a smart key, but recently also implemented as a smart phone, the "transponder" herein is not limited to a smart key, but a variety of devices such as smart phones It may be implemented using, and may be implemented to use a variety of radio signals such as Bluetooth, Wi-Fi, as well as LF signal, UHF signal.

In operation 332, the transponder 320 may determine the validity of the received command using a beep and transmit a response signal including a response if the command is valid. For example, the transponder 320 receives a radio signal transmitted from the base station 310 through the antenna, thereby receiving a command including [device identification number, current time, identification number and MAC of a randomly generated tone]. It is possible to receive, and through the microphone can receive a signal sound that is encoded with the [identification number]. A method of determining the validity of the command will be described in more detail later with reference to FIG. 4. As already described, the beeper may be randomly generated.

In step 333, the transponder 320 determines the validity of the received response and, if the response is valid, executes a predetermined operation. As described above, the predetermined operation may include various operations for remotely controlling a specific device, such as unlocking the vehicle, making an engine start, unlocking the front door, and the like.

If necessary, the transponder 320 may maintain a normal sleep mode. At this time, the base station 310 transmits a wake-up signal to the transponder 320 before performing the step 331 to switch the transponder 320 to the wake-up mode so that the transponder 320 The call can be controlled to transmit and receive data. The transponder 320 may transmit a response signal to the base station 310 after the transition to the wake-up mode, in which case the base station 310 performs a step 331 to transmit a command to the transponder 320. It may be.

4 is a flowchart illustrating a response method according to an embodiment of the present invention. Steps 410 to 440 illustrated in FIG. 4 may be included in step 332 of FIG. 3 and performed by the transponder 320.

In step 410, the transponder 320 uses a key shared with the base station 310 to check whether the command's MAC is valid. That is, the transponder 320 may confirm that the received command is generated by the base station 310 through the validity check of the MAC. As described above, the MAC and the key of the MAC may be selectively used, and step 410 may be omitted as necessary.

In step 420, the transponder 320 uses the current time included in the command to check whether the command was generated within a valid time. The time check is for detecting a case where a third party temporarily stores and retransmits a radio signal transmitted from the base station 310. The time check will be described in more detail later.

In step 430, the transponder 320 calculates a difference value between the signal reception time and the radio signal reception time. Since the radio signal and the sound signal have a difference in the propagation speed, the distance between the base station 310 and the transponder 320 can be calculated based on the difference between the radio signal reception time and the audio signal reception time. At this time, the transponder 320, for example, may not always activate the microphone to receive a voice signal, but may activate a microphone for a predetermined time to receive a signal sound when a radio wave signal is received.

In step 440, if the calculated difference value is less than or equal to the predetermined value, the transponder 320 transmits a radio signal including a response to the base station 310. That is, the smaller the calculated difference value (more precisely, the absolute value of the difference value), the shorter the distance between the base station 310 and the transponder 320. Therefore, the transponder 320 can detect an abnormal state such as the above-described relay attack through the difference value, and when the difference value exceeds a preset value, the transponder 320 does not respond to the radio signal, thereby causing the relay attack. Can be blocked.

In addition, in another embodiment of the present invention, the base station 310 and the transponder 320 may not have the exact distance calculated as in the steps 430 and 440, but may have only the loudness of the beep or the arrival of the beep. You can also estimate the distance between them. For example, as described above, when the radio signal is received, the transponder 320 may activate a microphone for a predetermined time to receive a signal sound. Therefore, when the microphone is activated for a certain time and the reception sound does not reach within the corresponding time, an abnormal state such as a relay attack can be detected.

Referring to FIG. 3 again, the transponder 320 may transmit a voice through a radio signal or may transmit a voice. If the voice is transmitted through the beeper, if the distance between the base station 310 and the transponder 320 is greater than or equal to a certain distance, the relay attack may be blocked because the beep does not reach the base station 310.

In another embodiment, the base station 310 may encode and transmit the current time to the beep at step 331. In this case, the transponder 320 may calculate the distance by calculating a difference between the present time included in the signal sound and the arrival time of the radio signal.

If the user opens the vehicle door to access the vehicle or presses a button for opening the door through the smart key or the smartphone, the base station 310 stops the existing beeping signal and indicates that the door is opened in the vehicle. The alert may be sent another beep at the audible frequency.

As described above, according to embodiments of the present invention, since the distance between the base station and the transponder can be grasped by using the beeping signal, the above-mentioned radio relay attack can be easily blocked.

For example, an attacker can be divided into two types.

The first type of attacker is an attacker who is simultaneously located in separate locations of base stations and transponders that are far from each other and simply relays radio signals and tones. In this case, although the radio signal is relayed very quickly, the longer the distance, the longer the transmission time, the greater the difference between the arrival time of the radio signal and the arrival time of the signal. Thus, an attacker is difficult to trick the base station that the base station and the transponder are within a valid distance.

The second type of attacker is an attacker that is located in each of the base stations and transponders far apart from each other simultaneously and relays radio signals and tones, but keeps radio signals for a certain time and retransmits them. In this case, since the difference between the present time included in the radio signal and the time when the radio signal arrives at the transponder increases, the transponder can determine that the command of the received radio signal is invalid. Therefore, the relay attack can also be easily blocked.

5 is a flowchart illustrating an authentication method according to an embodiment of the present invention. The authentication method according to the present embodiment relates to a method for authenticating a base station in a transponder, and may be performed by the transponder 320 described with reference to FIGS. 3 and 4.

In operation 510, the transponder 320 may receive radio signals and tones from the base station. Here, the radio wave signal may include an identification number of a device including a base station, a time when a radio signal is transmitted from the base station, and an identification number of a signal tone. In addition, the tone may be encoded and generated to include at least the identification number of the tone. At this time, the radio signal may further include a MAC, if necessary, in this case, the key necessary for the calculation of the MAC between the base station and the transponder 320 may be shared in advance.

In operation 520, the transponder 320 may determine whether the radio signal is valid according to at least one of a difference between a reception time of the signal sound and a reception time of the radio signal, a magnitude of the signal sound, and whether or not the signal sound is received.

For example, the transponder 320 may determine whether the radio signal is valid using the difference between the reception times of the sound signal and the radio signal in step 520. That is, since radio waves and sounds are different from each other in speed of air transmission, even when radio signals and signal tones are simultaneously transmitted from the base station, the time to reach the transponder 320 is different from each other, and the transponder 320 ), The farther the distance between the base station and the base station, the greater the difference between the reception times. In other words, the difference between the reception times is proportional to the distance between the transponder 320 and the base station. In this case, the transponder 320 may determine that the radio signal is valid when the difference between the reception times is less than or equal to the valid value. Here, the effective value may be preset in advance based on the effective distance between the transponder 320 and the base station. If necessary, the transponder 320 may calculate the distance between the transponder 320 and the base station using the difference value and determine whether the radio signal is valid by comparing the calculated distance with the effective distance. have.

As another example, the transponder 320 may determine whether the radio signal is valid using the loudness of the signal in operation 530. That is, the loudness of the beeper is inversely proportional to the distance between the transponder 320 and the base station. Accordingly, the transponder 320 may determine that the radio wave signal is valid when the loudness of the signal is greater than or equal to the preset loudness.

Similarly, the transponder 320 may determine whether the radio signal is valid using the reception of the beep sound in step 530. At this time, the base station may adjust the output strength of the signal sound so that the signal sound reaches only a predetermined distance, and the transponder 320 may determine that the radio signal is valid when the signal sound is received.

In addition, as described above, the radio signal may include an identification number of the device including the base station, the time when the radio signal is transmitted from the base station and the identification number of the beeping sound, and the beeping sound includes at least the identification number of the beeping sound. Can be encoded and generated. In this case, the transponder 320 may further perform an operation (not shown) by comparing the identification number of the signal sound included in the radio signal with the identification number extracted from the signal sound (not shown). As such, determining whether the signal tone is valid may be performed before or after step 320.

In addition, the transponder 320 may further perform a step (not shown) of additionally determining whether the radio signal is valid based on a difference between a reception time of the radio signal and a transmission time of the radio signal. As described above, the third party may store and retransmit the radio signal for a short time in order to reduce the difference between the reception times of the radio signal and the sound signal for the relay attack. Accordingly, in order to prevent such a relay attack, the transponder 320 may further determine whether the radio signal is valid based on the difference between the reception time and the transmission time of the radio signal.

In step 530, if it is determined that the radio signal is valid, the transponder 320 may transmit a response signal including the response to the base station. At this time, the validity of the response is determined at the base station, and if the response is valid, a predetermined operation may be performed at the base station. For example, the predetermined operation may be an operation for remotely controlling the device such as unlocking the vehicle or the door, starting the engine of the vehicle, and the like. That is, when the user carrying the smart key including the transponder 320 approaches within the effective distance of the vehicle, the device may be controlled to automatically unlock the vehicle or start the engine.

6 is a flowchart illustrating an operating method according to an embodiment of the present invention. The operation method according to the present embodiment may be performed by the base station 310 described with reference to FIGS. 3 and 4.

In step 610, the base station 310 transmits radio signals and tones to the transponder. Here, the radio signal may include an identification number of the device including the base station 310, the time when the radio signal is transmitted from the base station 310 and the identification number of the signal tone. In addition, the tone may be encoded and generated to include at least the identification number of the tone. At this time, the radio signal may further include a MAC, if necessary, in this case, the key necessary for the calculation of the MAC between the base station 310 and the transponder may be shared in advance. In addition, the radio wave signal may be transmitted through the antenna and the signal sound may be transmitted through the speaker.

In this case, the validity of the radio signal may be determined using at least one of a difference between the reception time of the signal sound and the reception time of the radio signal, the magnitude of the signal sound, and whether the signal sound is received in the transponder.

For example, the transponder may determine whether the radio signal is valid by using a difference value between reception times of the signal sound and the radio signal. That is, since radio waves and sounds are transmitted at different speeds, even when a radio signal and a signal sound are simultaneously transmitted from the base station, the time of arrival at the transponder is different from each other, and the transponder and the base station 310 are different. The greater the distance between the two, the greater the difference between the reception times. In other words, the difference between the reception times is proportional to the distance between the transponder and the base station 310. In this case, the transponder may determine that the radio signal is valid when the difference between the reception times is less than or equal to the valid value. Here, the effective value may be preset in advance based on the effective distance between the transponder and the base station 310. If necessary, the transponder may calculate the distance between the transponder and the base station 310 by using the difference value, and determine whether the radio signal is valid by comparing the calculated distance with the effective distance.

As another example, the transponder may determine whether the radio signal is valid using the loudness of the signal. That is, the loudness of the beeper is inversely proportional to the distance between the transponder and the base station 310. Accordingly, the transponder may determine that the radio wave signal is valid when the loudness of the signal is greater than or equal to the preset loudness.

Similarly, the transponder may determine whether the radio signal is valid by using the reception of the beep. In this case, the base station 310 may adjust and output the transmission strength of the signal sound so that the signal sound reaches only a predetermined distance, and the transponder may determine that the radio signal is valid when the signal sound is received.

In addition, as described above, the radio signal may include an identification number of a device including the base station 310, an identification number of a time and a signal tone at which the radio signal is transmitted from the base station 310, and the signal tone is a beep sound. It may be encoded and generated to include at least an identification number of. In this case, the transponder may determine whether the signal tone is valid by comparing the identification number of the signal tone included in the radio signal with the identification number extracted from the signal tone.

In addition, the transponder may further determine whether the radio signal is valid based on the difference between the reception time of the radio signal and the transmission time of the radio signal. As described above, the third party may store and retransmit the radio signal for a while to reduce the difference between the reception times of the radio signal and the signal sound for the relay attack. Therefore, in order to prevent such a relay attack, the transponder may further determine whether the radio signal is valid based on the difference between the reception time and the transmission time of the radio signal.

In step 620, the base station 310 receives the response signal generated from the transponder based on the radio signal and the signal tone. If it is determined that the radio signal is valid, the transponder may transmit a response signal including the response to the base station 310. The base station 310 may receive the response signal in step 620 to check the response included in the response signal.

In step 630, if it is determined that the response included in the response signal is valid, the base station 310 performs a predetermined operation. For example, the predetermined operation may be an operation for remotely controlling the device such as unlocking the vehicle or the door, starting the engine of the vehicle, and the like. That is, when the user carrying the smart key including the transponder approaches within the effective distance from the vehicle, the device may be controlled to automatically unlock the vehicle or start the engine.

FIG. 7 is a block diagram illustrating an internal configuration of a base station and a transponder according to an embodiment of the present invention. 7 shows a base station device 710 and a transponder device 720, respectively. In this case, the base station apparatus 710 may correspond to the base station 310 described with reference to FIGS. 3, 4, and 6. Also, the transponder device 720 may correspond to the transponder 320 described with reference to FIGS. 3 to 5.

The base station apparatus 710 may include a transmitter 711, a response signal receiver 712, and an operation performer 713. The transponder apparatus 720 may include a receiver 721 and a validity checker 722. ) And a response signal transmitter 723.

The transmitter 711 may transmit a radio signal and a signal sound to the transponder device 720. In this case, the radio wave signal may include an identification number of a device including the base station apparatus 710, an identification number of a time and a signal tone at which the radio signal is transmitted from the base station apparatus 710, and the base station apparatus 710 or The base station device 710 may be transmitted through the antenna of the device included. In addition, the signal tone may be encoded and generated to include at least an identification number of the tone, and may be transmitted through a speaker of a device including the base station apparatus 710 or the base station apparatus 710.

The receiver 721 may receive a radio signal and a signal sound from the base station apparatus 710. In this case, the radio wave signal may be received through the antenna of the transponder device 720 or the device including the transponder device 720, the signal tone is a device containing the transponder device 720 or transponder device 720 Can be received via a microphone.

The validity determination unit 722 may determine whether the radio signal is valid by using at least one of a difference between the reception time of the signal sound and the reception time of the radio signal, the magnitude of the signal sound, and whether the signal sound is received.

For example, the transponder device 720 may determine whether the radio signal is valid by using the difference between the reception times of the signal sound and the radio signal. That is, since radio waves and sounds are transmitted at different speeds, even when a radio signal and a signal sound are simultaneously transmitted from the base station, the time to reach the transponder device 720 is different from each other. As the distance between the 720 and the base station apparatus 710 increases, the difference between the reception times becomes larger. In other words, the difference between the reception times is proportional to the distance between the transponder device 720 and the base station device 710. In this case, the transponder device 720 may determine that the radio wave signal is valid when the difference between the reception times is less than or equal to the valid value. Here, the effective value may be preset in advance based on the effective distance between the transponder device 720 and the base station device 710. If necessary, the transponder device 720 calculates the distance between the transponder device 720 and the base station device 710 by using the difference value, and validates the radio signal by comparing the calculated distance with the effective distance. You can also determine whether or not.

As another example, the transponder device 720 may determine whether the radio signal is valid by using the loudness of the signal sound. That is, the loudness of the beeper is inversely proportional to the distance between the transponder device 720 and the base station device 710. Accordingly, the transponder device 720 may determine that the radio wave signal is valid when the loudness of the signal is greater than or equal to the preset loudness.

Similarly, the transponder apparatus 720 may determine whether the radio signal is valid by using the reception of the signal sound. At this time, the base station apparatus 710 may adjust the output strength of the signal sound so that the signal sound reaches only a predetermined distance, and the transponder device 720 may determine that the radio signal is valid when the signal sound is received. have.

In addition, as described above, the radio wave signal may include an identification number of a device including the base station apparatus 710, an identification number of a time and a signal tone at which the radio signal is transmitted from the base station apparatus 710, and a beep sound. May be encoded and generated to include at least the identification number of the tone. In this case, the transponder device 720 may determine whether the signal sound is valid by comparing the identification number of the signal sound included in the radio signal with the identification number extracted from the signal sound.

In addition, the transponder apparatus 720 may further determine whether the radio signal is valid based on the difference between the reception time of the radio signal and the transmission time of the radio signal. As described above, the third party may store and retransmit the radio signal for a while to reduce the difference between the reception times of the radio signal and the signal sound for the relay attack. Accordingly, in order to prevent such a relay attack, the transponder device 720 may further determine whether the radio signal is valid based on the difference between the reception time and the transmission time of the radio signal.

When it is determined that the radio signal is valid, the response signal transmitter 723 transmits the response signal including the response to the base station apparatus 710. In this case, the response signal may be transmitted to the base station device 710 through at least one of a radio wave signal and a signal sound generated through the transponder device 720.

The response signal receiving unit 712 receives the response signal generated from the transponder device 720 based on the radio signal and the sound signal, and the operation performing unit 713 determines that the response included in the response signal is valid. Perform the set operation. For example, the predetermined operation may be an operation for remotely controlling the device such as unlocking the vehicle or the door, starting the engine of the vehicle, and the like. That is, when a user with a smart key including the transponder device 720 approaches the vehicle within the effective distance of the vehicle including the base station device 710, the vehicle is automatically unlocked or the engine is not started. The device can be controlled to catch.

As described above, according to embodiments of the present invention, the distance between the remote devices can be confirmed using a sound signal such as a beep so that the vehicle or a specific device can be remotely controlled safely.

The apparatus described above may be implemented as a hardware component, a software component, and / or a combination of hardware components and software components. For example, the apparatus and components described in the embodiments may be implemented within a computer system, such as, for example, a processor, a controller, an arithmetic logic unit (ALU), a digital signal processor, a microcomputer, a field programmable array (FPA) A programmable logic unit (PLU), a microprocessor, or any other device capable of executing and responding to instructions. The processing device may execute an operating system (OS) and one or more software applications running on the operating system. The processing device may also access, store, manipulate, process, and generate data in response to execution of the software. For ease of understanding, the processing apparatus may be described as being used singly, but those skilled in the art will recognize that the processing apparatus may have a plurality of processing elements and / As shown in FIG. For example, the processing unit may comprise a plurality of processors or one processor and one controller. Other processing configurations are also possible, such as a parallel processor.

The software may include a computer program, code, instructions, or a combination of one or more of the foregoing, and may be configured to configure the processing device to operate as desired or to process it collectively or collectively Device can be commanded. The software and / or data may be in the form of any type of machine, component, physical device, virtual equipment, computer storage media, or device , Or may be permanently or temporarily embodied in a transmitted signal wave. The software may be distributed over a networked computer system and stored or executed in a distributed manner. The software and data may be stored on one or more computer readable recording media.

The method according to an embodiment may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions to be recorded on the medium may be those specially designed and configured for the embodiments or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

310: base station
320: transponder

Claims (19)

In a method for authenticating a base station in a transponder,
Receiving radio signals and tones from the base station;
Determining whether the radio signal is valid using at least one of a difference value between a reception time of the signal tone and a reception time of the radio signal, the magnitude of the signal tone, and whether the signal tone is received; And
If it is determined that the radio wave signal is valid, transmitting a response signal including a response to the base station.
Lt; / RTI >
And if the response is determined to be valid at the base station, and if the response is valid, a predetermined operation is performed at the base station. The method of claim 1,
Determining whether the radio signal is valid,
And when the difference is less than or equal to a preset valid value based on the effective distance between the transponder and the base station, determining that the radio signal is valid. The method of claim 1,
Determining whether the radio signal is valid,
Calculating a distance between the transponder and the base station based on the difference value; And
And if the calculated distance is less than or equal to the effective distance between the transponder and the base station, determine that the radio signal is valid. The method of claim 1,
Determining whether the radio signal is valid,
And when the loudness is greater than or equal to a preset loudness based on the effective distance between the transponder and the base station, determining that the radio signal is valid. The method of claim 1,
Determining whether the radio signal is valid,
If the signal tone is received, it is determined that the radio signal is valid,
The signal tone is an authentication method, characterized in that the transmission strength is preset based on the effective distance between the transponder and the base station in the base station. The method of claim 1,
The radio signal includes an identification number of a device including the base station, a transmission time of the radio signal in the base station and an identification number of the signal tone,
And the tone is encoded and generated to include at least the identification number of the tone. The method according to claim 6,
Comparing the identification number of the signal tone included in the radio signal with the identification number extracted from the signal tone to determine whether the signal tone is valid;
Authentication method further comprising. The method according to claim 6,
Further determining whether the radio signal is valid based on a difference between a reception time of the radio signal and a transmission time of the radio signal;
Authentication method characterized in that it further comprises. The method according to claim 6,
The radio signal further comprises a message authentication code (MAC) calculated using a key shared in advance between the transponder and the base station. In the operation method of the base station,
Transmitting a radio signal and a tone to a transponder;
Receiving a response signal generated from the transponder on the basis of the radio wave signal and the tone; And
If it is determined that the response included in the response signal is valid, performing a preset operation.
Lt; / RTI >
The transponder determines whether the radio signal is valid using at least one of a difference value between a reception time of the signal tone and a reception time of the radio wave signal, a magnitude of the signal tone, and whether the signal tone is received.
And the response signal is transmitted when the radio signal is determined to be valid by the transponder. 11. The method of claim 10,
And the propagation signal is determined to be valid when the difference value is equal to or less than a preset valid value based on the effective distance between the transponder and the base station. 11. The method of claim 10,
And wherein the radio signal is determined to be valid when the distance between the transponder and the base station calculated based on the difference value is less than or equal to the effective distance between the transponder and the base station. 11. The method of claim 10,
And the propagation signal is determined to be valid when the loudness is greater than or equal to a preset loudness based on the effective distance between the transponder and the base station. 11. The method of claim 10,
The signal tone has a preset transmission intensity based on the effective distance between the base station and the transponder,
And wherein the radio signal is determined to be valid when the signal tone is received. 11. The method of claim 10,
The radio signal includes an identification number of a device including the base station, a transmission time of the radio signal in the base station and an identification number of the signal tone,
And the tone is encoded and generated to include at least the identification number of the tone. A transponder device that authenticates a base station,
A receiving unit which receives radio signals and tones from the base station;
An effective determining unit determining whether the radio signal is valid using at least one of a difference between the reception time of the signal tone and the reception time of the radio signal, the magnitude of the signal tone, and whether the signal tone is received; And
If it is determined that the radio signal is valid, the response signal transmission unit for transmitting a response signal containing a response to the base station
Lt; / RTI >
The base station determines whether the response is valid, and if the response is valid, a predetermined operation is performed in the base station. A base station apparatus,
A transmission unit for transmitting radio signals and tones to a transponder;
A response signal receiving unit receiving a response signal generated from the transponder based on the radio wave signal and the signal tone; And
If it is determined that the response included in the response signal is valid, an operation execution unit for performing a predetermined operation
Lt; / RTI >
The transponder determines whether the radio signal is valid using at least one of a difference value between a reception time of the signal tone and a reception time of the radio wave signal, a magnitude of the signal tone, and whether the signal tone is received.
And the response signal is transmitted when the radio signal is determined to be valid by the transponder. A computer readable storage medium containing instructions for authenticating a base station by a computer system, comprising:
The command includes:
Receiving radio signals and tones from the base station;
Determining whether the radio signal is valid using at least one of a difference value between a reception time of the signal tone and a reception time of the radio signal, the magnitude of the signal tone, and whether the signal tone is received; And
If it is determined that the radio wave signal is valid, transmitting a response signal including a response to the base station.
Lt; / RTI >
And if the response is determined to be valid at the base station, and if the response is valid, a predetermined operation is performed at the base station. A computer readable storage medium comprising instructions for a computer system to perform a predetermined operation, the computer readable storage medium comprising:
The command includes:
Transmitting a radio signal and a tone to a transponder;
Receiving a response signal generated from the transponder on the basis of the radio wave signal and the tone; And
If it is determined that the response included in the response signal is valid, performing a preset operation.
Lt; / RTI >
The transponder determines whether the radio signal is valid using at least one of a difference value between a reception time of the signal tone and a reception time of the radio wave signal, a magnitude of the signal tone, and whether the signal tone is received.
And the response signal is transmitted when the radio signal is determined to be valid by the transponder.

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