KR101230369B1 - The door-lock apparatus available to prevent hacking and method for authenticating smart-keys using the same - Google Patents

Abstract

The present invention relates to a door lock device capable of preventing hacking and a smart key authentication method using the same, and checks whether an RF signal received from the smart key has a hacking possibility, and only when the RF key received from the smart key is identified as a normal RF signal without hacking possibility. By performing authentication on, it is possible to minimize the possibility of unauthorized intrusion due to hacking.

Description

The door-lock apparatus available to prevent hacking and method for authenticating smart-keys using the same}

The present invention relates to a door lock device capable of preventing hacking and a smart key authentication method using the same, and more specifically, only if the RF signal received from the smart key is confirmed as a normal RF signal without hacking possibility by checking whether there is a hacking possibility. It relates to a door lock device that can minimize the risk of hacking by performing the authentication for the smart key and smart key authentication method using the same.

In general, a mechanical door lock that uses a key to open and close a door is mainly used as a door lock device for an office, a hotel, an apartment, a factory, and the like. However, the conventional mechanical door lock must be carried by the user when the user must go out, if the key is lost can not open and close the door, there is a problem that the security of the weakness of the key is easy to duplicate.

Due to these problems, a digital door lock of a type that opens and closes a door using a security card or a password is widely used these days. However, in the case of the digital door lock, there is a problem in that inconvenience is still present from the user's point of view because it requires a series of actions for user authentication, for example, contact of a security card, input of a password, etc. in order to unlock the door. .

For example, in the case of a door lock using a security card, when the user touches the security card to the door lock, the card reader inside the door lock checks the information registered on the security card, and then unlocks the door. In order to solve the inconvenience, the user must remove the security card from the pocket or the bag and contact the door lock.

In addition, in the case of a door lock using a password, if the user enters the password through the keypad mounted on the door lock, it controls to open and close the door by checking whether it matches the registered password, the user through the keypad to unlock There is a problem that still comes with inconvenience because you must press directly. In addition, there are many unspecified people entering and leaving the institute or the company, so there is a risk of password leakage when the user presses the password.In the absence of the user, the visitor must be informed of the password and the user must change the password. There is discomfort.

In order to solve this problem, recently, a non-contact door lock device has been disclosed that further enhances user convenience by allowing a user to release a lock by simply carrying a smart key using RFID technology.

Figure 1a is a view showing a conventional contactless door lock device, Figure 1b is a view for explaining a hacking problem that may occur in the conventional contactless door lock device.

Referring to FIG. 1A, a conventional non-contact door lock device transmits a low frequency (LF) signal from a door lock main body 10 to a smart key 20 within a communication range, and activates the smart key 20. Receives an RF (Radio Frequency) signal including a smart key ID as a response to the LF signal from the smart key 20, and performs authentication on the corresponding smart key 20 based on the smart ID, thereby making authentication successful. To operate the door in the unlocked state.

However, as shown in Figure 1b, in the case of the conventional contactless door lock device, since the RF signal transmitted from the smart key 20 can be easily retransmitted at a long distance through the radio repeater 30, a malicious third Hacking the RF signal transmitted from the smart key 20 through the self-propagating repeater 30 there is a risk of illegally opening the door from a long distance without the user's knowledge.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is to check whether the RF signal received from the smart key is likely to be hacked only when confirmed as a normal RF signal without the possibility of hacking By authenticating the smart key, the risk of hacking is minimized.

In order to achieve the above object, a door lock device capable of preventing hacking according to an embodiment of the present invention includes a smart key storing authentication information necessary for authentication; And a rolling code for transmitting a low frequency (LF) signal for activating the smart key to the smart key existing within a communication range, and confirming the authentication information and the hacking possibility as a response to the LF signal from the smart key. Receives a radio frequency (RF) signal containing a, and if it is determined that the RF signal is a normal RF signal with no hacking possibility based on the rolling code included in the RF signal, the authentication information included in the RF signal It characterized in that it comprises a door lock body for operating the door in the unlocked state if the authentication is successful by performing the authentication on the smart key based on.

Preferably, the door lock body, The door lock body, LF transmitter for transmitting the LF signal to the smart key present in the communication range; An RF receiver configured to receive the RF signal including the authentication information and the rolling code as a response to the LF signal from the smart key; A hacking determination unit determining whether the RF signal is a normal RF signal without hacking possibility based on the rolling code included in the RF signal; A smart key authenticator configured to authenticate the smart key based on the authentication information included in the RF signal when it is determined that the RF signal is a normal RF signal without hacking possibility; And if the authentication of the smart key is successful, operate the door in an unlocked state, and if it is determined that the RF signal is an abnormal RF signal that may be hacked through the hacking determination unit, discard the RF signal and operate the door in the locked state. It is characterized in that it comprises a door lock control unit for notifying the possibility of hacking through the screen.

Preferably, the smart key, LF receiving unit for receiving the LF signal transmitted from the door lock body; A smart key controller for activating a corresponding smart key in response to the received LF signal and generating the RF signal including the rolling code capable of confirming the authentication information and the hacking possibility; And an RF transmitter for transmitting the generated RF signal to the door lock body.

Preferably, the rolling code is incremented by one each time the RF signal is transmitted, characterized in that the number of transmission of the RF signal.

Preferably, the hacking determination unit, when the rolling code included in the RF signal has a value of '1', the RF signal is directly transmitted from the smart key determines that there is no hacking possibility is a normal RF signal, When the rolling code included in the RF signal has a value of '2' or more, it is determined that the RF signal is an abnormal RF signal that may be hacked after being retransmitted through at least one radio repeater after being transmitted from the smart key. It is characterized by.

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On the other hand, the smart key authentication method according to an embodiment of the present invention, (a) the door lock body transmits a LF (Low Frequency) signal for the activation of the smart key to the smart key existing within the communication range, and to the smart key Receiving a radio frequency (RF) signal including a rolling code for confirming hacking possibility and authentication information of the smart key as a response to the LF signal; (b) determining whether the RF signal is a normal RF signal without hacking possibility based on the rolling code included in the RF signal; And (c) if it is determined that the RF signal is a normal RF signal without hacking possibility, performs authentication on the smart key based on the authentication information included in the RF signal, and if the authentication is successful, unlocks the door. If the RF signal is determined to be an abnormal RF signal that is likely to be hacked, discarding the RF signal and operating the door in a locked state, characterized in that it comprises the step of notifying the possibility of hacking through the screen.

Preferably, the rolling code is incremented by one each time the RF signal is transmitted, characterized in that the number of transmission of the RF signal.

Preferably, in the step (b), when the rolling code included in the RF signal has a value of '1', it is determined that the RF signal is a normal RF signal with no possibility of hacking since it is transmitted directly from the smart key. In the first step, and when the rolling code included in the RF signal has a value greater than or equal to '2', the RF signal is transmitted from the smart key and then retransmitted through at least one radio repeater to be hacked. And a second step of determining that the signal is an RF signal.

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According to the present invention, it is possible to minimize the risk of hacking by verifying whether the RF signal received from the smart key has a hacking possibility and performing authentication for the corresponding smart key only when it is confirmed as a normal RF signal without hacking possibility. It works.

Figure 1a is a view showing a conventional non-contact door lock device.
1B is a view for explaining a hacking problem that may occur in the conventional contactless door lock device.
2 is a view for explaining the configuration and operation of the door lock device according to an embodiment of the present invention.
3 is a diagram illustrating a smart key authentication method according to an embodiment of the present invention.
4 is a diagram illustrating a data frame structure of an RF signal used in the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the technical idea of the present invention. In the following description of the preferred embodiments of the present invention, when it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted or briefly described.

2 is a view for explaining the configuration and operation of the door lock device according to an embodiment of the present invention.

Referring to FIG. 2, the door lock device according to the exemplary embodiment of the present invention includes a door lock body 100 and a smart key 200.

The smart key 200 stores a smart key ID (for example, RFID) as authentication information for authentication of the smart key, and the door lock main body 100 receives the authentication information from the smart key 200. When the included RF signal is received, the smart key 100 is authenticated based on the authentication information included in the RF signal, and if the authentication is successful, the door is operated in an unlocked state.

The door lock main body 100 is an LF transmitter 110 for transmitting a low frequency (LF) signal for activation of the smart key 200 to the smart key 200 existing within the LF communication range, and the smart key 200 RF receiver 120 for receiving a (Radio Frequency) signal containing the authentication information as a response to the LF signal, and the hacking determination unit 130 for determining whether the RF signal is a normal RF signal without hacking possibility And a smart key authentication unit 140 for authenticating the smart key 200 based on authentication information included in the RF signal when it is determined that the RF signal is a normal RF signal without hacking possibility. If the authentication is successful for the smart key is configured to include a door lock control unit 150 for operating the door in the unlocked state.

The smart key 200 is an LF receiver 210 for receiving the LF signal transmitted from the door lock main body 100, and in response to the received LF signal to activate the corresponding smart key and RF containing the authentication information It comprises a smart key controller 230 for generating a signal, and an RF transmitter 250 for transmitting the generated RF signal to the door lock body 100.

That is, in the non-contact door lock device of the present invention, the door lock body 100 receives the authentication information included in the RF signal only when the RF signal received through the RF receiver 120 is a normal RF signal without hacking possibility. Based on the authentication for the smart key 200 is performed.

Therefore, in the case of the conventional non-contact door lock device, there is a risk of illegally opening the door at a long distance without the user's knowledge by hacking the RF signal transmitted from the smart key 20 using the radio repeater 30 as described above. The non-contact door lock device of the present invention performs authentication for the smart key 200 only when the RF signal received from the smart key 200 is confirmed as a normal RF signal without hacking possibility, thereby minimizing the risk due to hacking. have.

Hereinafter, a smart key authentication method according to the present invention will be described in more detail.

3 is a diagram illustrating a smart key authentication method according to an embodiment of the present invention.

Referring to FIG. 3, when the door lock main body 100 transmits a low frequency (LF) signal from the door lock main body 100 to a smart key 200 within a range capable of LF communication (S301), the smart key 200 transmits the LF signal. Receives and checks whether the smart key ID included in the LF signal matches its own smart key ID (S311 to S313).

Here, the LF signal is to wake-up the smart key 200 in a sleep state, and the LF signal preferably includes a smart key ID for activating the corresponding smart key. Do.

When the smart key ID included in the LF signal matches its own smart key ID, the smart key 200 is activated. Accordingly, the smart key 200 responds to the LF signal by RF (Radio Frequency). The signal is generated and transmitted to the door lock body 100 (S315 to S317).

Here, the RF signal includes authentication information necessary for authentication of the smart key 200 and security information for confirming the possibility of hacking of the RF signal, which will be described with reference to FIG. 4.

4 is a diagram illustrating a data frame structure of an RF signal used in the present invention.

Referring to FIG. 4, the data frame of the RF signal used in the present invention includes a command code 410 indicating a control command (eg, lock / unlock, smart key registration, etc.) associated with a door lock. Function code 420 indicating a function for executing a control command, ID 430 of the smart key, rolling code 440 indicating the number of times of RF signal transmission, and encryption of the RF signal The included encryption code 450, a VLOW code 460 of the smart key, a cyclic redundancy check code 470 for error detection and correction of an RF signal, and the like.

Here, the rolling code 440 is sequentially increased by 1 each time the RF signal is transmitted, indicating the number of times that the RF signal is transmitted, and when the rolling code 440 has a value of '1' Means that the RF signal is transmitted directly from the smart key 200, and if the value has a value of '2' or more, the RF signal has been retransmitted through at least one radio repeater after being transmitted from the smart key 200. it means.

That is, the rolling code 440 may determine whether the RF signal is directly transmitted from the smart key 200 or retransmitted through the radio repeater.

Next, when the door lock main body 100 receives an RF signal (S321), it is determined whether the RF signal is a normal RF signal without hacking possibility based on the rolling code 440 included in the RF signal (S323). ).

In this case, when the rolling code 440 has a value of '1', it means that the RF signal is transmitted directly from the smart key 200. Therefore, it is determined that the RF signal is a normal RF signal without hacking possibility. If the rolling code 440 has a value greater than or equal to '2', it means that the RF signal is retransmitted through at least one radio repeater after being transmitted from the smart key 200. It is determined that this is an abnormal RF signal.

If it is determined that the RF signal is a normal RF signal without hacking possibility, the door lock main body 100 checks whether the smart key ID included in the RF signal matches the registered smart key ID (S325), and if the corresponding smart The key 200 is authenticated and the door is operated in the unlocked state (S327). If the key 200 is not matched, the door is operated in the locked state (S329).

If it is determined that the RF signal is an abnormal RF signal that may be hacked, the door lock main body 100 discards the RF signal (S331), and notifies the possibility of hacking through the screen while operating the door in a locked state ( S333).

That is, according to the conventional smart key authentication method, since the door lock main body 10 side cannot know the possibility of hacking the RF signal transmitted from the smart key 20 at all, if the authentication for the smart key 20 succeeds, the door is opened. It operates in the unlocked state, which may cause unauthorized intrusion and theft accidents.

On the other hand, according to the smart key authentication method of the present invention, the door lock main body 100 side checks whether the RF signal transmitted from the smart key 200 is hacking possibility confirmed as a normal RF signal without hacking possibility Since only the authentication for the smart key 200 is performed, the possibility of unauthorized intrusion due to hacking can be minimized.

Meanwhile, in the present embodiment, it is determined whether the RF signal transmitted from the smart key 200 to the door lock main body 100 is a normal RF signal without hacking possibility, and the reason is the RF transmitted from the smart key 200. The signal can be easily retransmitted at a long distance through a radio repeater, so that there is a high risk of hacking, and the LF signal transmitted from the door lock body unit 100 has a short transmission distance, so that a large amount of current is required to retransmit the LF signal using a radio repeater. This is because the risk of hacking is not great. However, according to an application example, as shown in FIG. 4, the LF signal may include a rolling code indicating the number of transmissions of the LF signal and may be transmitted, and the smart key may determine whether the LF signal is normal.

So far, the present invention has been described based on the preferred embodiments. However, embodiments of the present invention is provided to those skilled in the art to more fully describe the present invention, the scope of the present invention is not limited to the above embodiments, various other Of course, the shape can be modified.

100: door lock body
110: LF transmitter
120: RF receiver
130: hacking judgment unit
140: smart key authentication unit
150: door lock control unit
200: smart key
210: LF receiver
230: smart key controller
250: RF transmitter

Claims (12)

Smart key that stores the authentication information required for authentication,
A rolling code for transmitting a low frequency (LF) signal for activating the smart key to the smart key existing within a communication range, and confirming the authentication information and the hackability as a response to the LF signal from the smart key. Receiving an included RF (Radio Frequency) signal, if it is determined that the RF signal is a normal RF signal without hacking possibility based on the rolling code included in the RF signal, the authentication information included in the RF signal And a door lock main body which operates the door in an unlocked state when authentication is successful by performing authentication on the smart key based on the result.
The rolling code is sequentially incremented by one each time the RF signal is transmitted to indicate the number of transmissions of the RF signal.
The door lock body,
An LF transmitter for transmitting the LF signal to the smart key existing within a communication range;
An RF receiver configured to receive the RF signal including the authentication information and the rolling code as a response to the LF signal from the smart key;
A hacking determination unit determining whether the RF signal is a normal RF signal without hacking possibility based on the rolling code included in the RF signal;
A smart key authenticator configured to authenticate the smart key based on the authentication information included in the RF signal when it is determined that the RF signal is a normal RF signal without hacking possibility; And
If the authentication of the smart key is successful, the door is operated in an unlocked state. If the RF signal is determined to be an hackable abnormal RF signal through the hacking determination unit, the RF signal is discarded and the door is operated in a locked state. It includes a door lock control unit to notify the possibility of hacking through the screen,
The hacking determination unit,
When the rolling code included in the RF signal has a value of '1', it is determined that the RF signal is a normal RF signal which is transmitted directly from the smart key and there is no possibility of hacking, and the rolling included in the RF signal If the code has a value of '2' or more, anti-hacking is possible, characterized in that the RF signal is transmitted from the smart key and then retransmitted through at least one radio repeater to determine that it is an abnormal RF signal that may be hacked. Door lock device.
delete The method of claim 1, wherein the smart key,
An LF receiver for receiving the LF signal transmitted from the door lock body;
A smart key controller for activating a corresponding smart key in response to the received LF signal and generating the RF signal including the rolling code capable of confirming the authentication information and the hacking possibility; And
Hacking prevention door lock device, characterized in that it comprises an RF transmitter for transmitting the generated RF signal to the door lock body.
delete delete delete delete (a) transmits a low frequency (LF) signal for activation of the smart key from the door lock body to a smart key existing within a communication range, and authenticates and hacks the authentication information of the smart key as a response to the LF signal from the smart key; Receiving a radio frequency (RF) signal including a rolling code capable of identifying a possibility;
(b) determining whether the RF signal is a normal RF signal without hacking possibility based on the rolling code included in the RF signal; And
(c) If it is determined that the RF signal is a normal RF signal without hacking possibility, the door is unlocked when authentication is successful by performing authentication on the smart key based on the authentication information included in the RF signal. And if it is determined that the RF signal is an abnormal RF signal that may be hacked, discarding the RF signal and operating the door in a locked state, indicating that the RF signal may be hacked.
The rolling code is sequentially incremented by one each time the RF signal is transmitted to indicate the number of transmissions of the RF signal.
In the step (b)
When the rolling code included in the RF signal has a value of '1', determining that the RF signal is a normal RF signal that is directly transmitted from the smart key and that there is no possibility of hacking;
When the rolling code included in the RF signal has a value of '2' or more, it is determined that the RF signal is an abnormal RF signal that may be hacked after being retransmitted through at least one radio repeater after being transmitted from the smart key. The smart key authentication method further comprises a second step.
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