KR20190084640A - Beacon location checking method - Google Patents

Abstract

The present invention relates to a method for identifying a location of a beacon within a communication range of a beacon manager and tracking a location of a lost beacon by moving out of the communication range. According to the present invention, the method comprises the steps of: providing a beacon with first beacon data including a chain initial value; receiving second beacon data including a first cipher text encrypted with a first hash value from the beacon; decrypting the first cipher text; and checking the decrypted first cipher text and determining whether the location of the beacon is within a communication range of the beacon manager.

Description

{BEACON LOCATION CHECKING METHOD}

The present invention relates to a method for locating a beacon, and more particularly, to a method for identifying a location of a beacon within a communication range of the beacon manager and for tracking a position of a lost beacon by moving outside the communication range.

As the computer, electronic, and Internet communication technologies have developed remarkably, various multimedia communication services have been provided using a wireless network.

Recently, the wireless communication network has been expanded to the areas of Internet of things (IOT) and Internet of Everything (IOE). As the area where the wireless communication network is utilized is expanded, The importance is growing. Such short-range communication may be exemplified by a beacon equipped with a communication network on the basis of Bluetooth or Wi-Fi Direct.

As the price of beacons becomes cheaper and the spread becomes more active, a variety of applications are being developed that utilize them. These applications can be used for various purposes by using location information that is verified by tracking the radio signal of the beacon. For example, a beacon may be associated with a QR code (Quick Response Code) to be used for promoting a product, or a movement path of a person having a beacon may be grasped to check the attendance of employees. In recent years, there have been developed application products for preventing loss by continuously tracking the location of a beacon-attached object on a mobile device owned by a user by attaching a beacon to the item possessed by the user.

Conventionally, a technique used for preventing loss using a beacon is configured such that a user's mobile device receives authentication information transmitted from a beacon and authenticates and tracks the terminal. To do this, even if mutual authentication is performed by sharing a secret key between the beacon and the mobile device, the information used for authentication must be periodically changed. However, when a random number is generated by using the current time to convert the authentication information, a malicious attacker can obtain a plaintext / ciphertext pair from a random number generated based on the current time.

A malicious attacker can use this plaintext and cipher pair to find the secret key, which can cause a fatal problem in the security of the local communication. Such a problem occurs because a general beacon terminal has a low capacity / low cost limitation and can not be equipped with a pure random number generator in a beacon terminal.

Thus, there is a need for a beacon positioning method that can maintain low capacity / low cost characteristics of a beacon terminal while having a strong security function.

Korean Patent Publication No. 10-2008-0087106

SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus and method for continuously checking whether a beacon is located within a communication range of a beacon manager for managing a beacon.

It is another object of the present invention to reduce the cost required for installation and use of beacon by using a hash chain in a security function required for location confirmation of a beacon so that the location can be confirmed without any additional configuration for the beacon.

It is another object of the present invention to provide a security function capable of confirming the location of a lost beacon even if the beacon is lost out of communication range of the beacon manager and in this process.

According to another aspect of the present invention, there is provided a beacon position checking method for a beacon manager, the method comprising: setting a chain initial value corresponding to each beacon; Providing first beacon data to the beacon; Receiving a first beacon value from the beacon, the first beacon data including a first cipher text encrypted with the first hash value, wherein the first hash value is computed using time information to the chain initial value of the first beacon data; ; Decrypting the first ciphertext of the second beacon data with a second hash value calculated using the chain initial value and the time information stored in the beacon manager; And decrypting the decrypted first ciphertext to determine whether the location of the beacon is within a communication range of the beacon manager; . ≪ / RTI >

Receiving the second beacon data from the beacon includes: calculating the first hash value by repeatedly applying a hash function to the chain initial value a number of times corresponding to the time information; Generating the first ciphertext including the first hash value using the first hash value; Receiving the second beacon data including the first cipher text from the beacon; . ≪ / RTI >

The first beacon data may further include at least one of identification information for identifying the beacon, authentication information for verifying whether the beacon is authenticated, and generation time information about a generation time of the chain initial value.

The time information may be calculated using the generation time information and the current time information.

The first cipher text may be further encrypted including the authentication information of the first beacon data.

The first cipher text may further include count information for counting the second beacon data repeatedly generated at a predetermined time interval.

Wherein the decoding step comprises the steps of: loading information corresponding to identification information of the beacon included in the received second beacon data; Calculating the second hash value using the chain initial value included in the loaded information and the time information; And decrypting the first cipher text of the second beacon data using the second hash value; . ≪ / RTI >

The method of claim 1, wherein the decrypting step includes a step of decrypting the second beacon data included in the decrypted first ciphertext and included in the decrypted first ciphertext and repeatedly generated at a predetermined time interval, And confirming the location of the beacon through the information.

Wherein the determining step determines that the beacon is lost if the authentication information and the count information of the first cipher text do not match the information stored in the beacon manager or the second beacon data is not received in a predetermined time unit Step.

Displaying a beacon loss warning and registering the beacon in a lost beacon list if the beacon is determined to be lost; As shown in FIG.

According to another aspect of the present invention, there is provided a method of confirming the location of a beacon in a beacon management server, the method comprising the steps of: Receiving first lost beacon data by a first beacon manager; Receiving from the first beacon manager second beacon data including the identification information of the first beacon manager and the first lost beacon data, the beacon being identified by the first beacon manager as a lost beacon; ; Providing third lost beacon data corresponding to the second lost beacon data to a second beacon manager that matches the beacon identification information; Receiving, from the second beacon manager, fourth lost beacon data including a chain initial value stored in the second beacon manager and a second cipher text encrypted using the time information; And comparing the first cipher text and the second cipher text to inform the second beacon manager of the location of the beacon; . ≪ / RTI >

Wherein the step of receiving the first lost beacon data by the first beacon manager includes: calculating a first hash value by repeatedly applying a hash function to the chain initial value a number of times corresponding to the time information; Generating the first ciphertext including the first hash value using the first hash value; And receiving the first lost beacon data including the first cipher text from the beacon by the first beacon manager; . ≪ / RTI >

The step of receiving the second lost beacon data from the first beacon manager may include determining whether the beacon is lost through the beacon management server whether the beacon identification information is included in the lost beacon list.

Wherein receiving the fourth lost beacon data from the second beacon manager comprises: identifying the beacon identification information from the third lost beacon data; Calculating a second hash value by repeatedly applying a hash function to the chain initial value assigned to the beacon by the second beacon manager a number of times corresponding to the time information; Generating the second cipher text including the second hash value using the second hash value; And receiving the fourth lost beacon data including the second cipher text from the second beacon manager; . ≪ / RTI >

The step of notifying the location of the beacon may include decrypting the first cipher text and the second cipher text and comparing at least one of the count information, the hash value, and the authentication information included in the first cipher text and the second cipher text Lt; / RTI >

The beacon is within the communication range of the first beacon manager and may be outside the communication range of the second beacon manager.

The beacon position determination method according to the embodiment of the present invention can continuously check whether the beacon is located within the communication range of the beacon manager for managing the beacon.

In addition, the beacon position checking method according to the embodiment of the present invention uses the hash chain in the security function required for the positioning of the beacon, so that the position can be confirmed without any additional configuration of the beacon, Thereby reducing the cost.

The present invention can identify the location of a lost beacon even if the beacon is lost out of communication range of the beacon manager, and can provide an improved security function in this process.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
FIG. 1 is a diagram for explaining a system for performing a beacon position determining method according to an embodiment of the present invention.
2 is a view for explaining a beacon position determining method according to an embodiment of the present invention.
FIG. 3 is another diagram for explaining the beacon position determining method of FIG. 2. FIG.
4 is a diagram for explaining the second beacon data receiving step of FIG. 2 in more detail.
5 is a diagram for explaining the first decrypting step of FIG. 2 in more detail.
FIG. 6 is another diagram for explaining the beacon position determining method of FIG. 2. FIG.
7 is a view for explaining a beacon position determining method according to another embodiment of the present invention.
FIG. 8 is another diagram for explaining the beacon position checking method of FIG. 7. FIG.
FIG. 9 is a diagram for explaining the first lost beacon data receiving step of FIG. 7 in more detail.
FIG. 10 is a diagram for explaining the third lost beacon data receiving step of FIG. 7 in more detail.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments will be described in detail below with reference to the accompanying drawings.

The following examples are provided to aid in a comprehensive understanding of the methods, apparatus, and / or systems described herein. However, this is merely an example and the present invention is not limited thereto.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification. The terms used in the detailed description are intended only to describe embodiments of the invention and should in no way be limiting. Unless specifically stated otherwise, the singular form of a term includes plural forms of meaning. In this description, the expressions "comprising" or "comprising" are intended to indicate certain features, numbers, steps, operations, elements, parts or combinations thereof, Should not be construed to preclude the presence or possibility of other features, numbers, steps, operations, elements, portions or combinations thereof.

It is also to be understood that the terms first, second, etc. may be used to describe various components, but the components are not limited by the terms, and the terms may be used to distinguish one component from another .

Hereinafter, exemplary embodiments of a web browser display apparatus and a web browser display method according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a diagram for explaining a system for performing a beacon position determining method according to an embodiment of the present invention.

Referring to FIG. 1, a system for performing a beacon position determination method according to an exemplary embodiment of the present invention may include a beacon 100, a beacon manager 200, and a beacon management server 300.

The beacon 100 may be attached to or installed on an object. A beacon 100 for transmitting a short distance signal for periodic positioning can be installed or attached to various objects such as a bag, a carrier, a key or a wallet. The beacons 100 shown in FIG. 1 are installed in objects that are portable or easy to move. However, unlike the example shown in FIG. 1, the beacons 100 may be fixed or may be installed in objects having a large size.

The beacon 100 may transmit a short distance signal using Bluetooth, Wi-Fi Direct, LTE D2D (Long Term Evolution Device to Device) or the like for short distance communication. To this end, the beacon 100 may be equipped with a communication module for short range communication.

The beacon manager 200 can perform close-range communication with the beacon 100. [ The beacon manager 200 may include various devices such as a smart phone, a PDA, a web pad, a tablet PC, a mobile device such as a notebook computer, or a desktop computer installed with or equipped with a device for communicating with the beacon 100 Can be illustrated. The beacon manager 200 may be provided with an application for communicating information to beacons 100 or for processing information transmitted from the beacons 100, and may include a processor and a memory for driving such applications.

The beacon manager 200 can communicate with the beacon management server 300 through a wired device such as a LAN (Local Area Network) or a wireless device using Wi-Fi, 3G or 4G communication. The beacon management server 300 can register information on each of the plurality of beacon managers 200. [ The beacon management server 300 may be an aggregate of a database, a registration server, an authentication server, and the like for integrally managing each beacon manager 200.

A method in which the beacon 100, the beacon manager 200, and the beacon management server 300 communicate with each other to confirm the position of the beacon will be described in detail with reference to the following drawings.

A beacon position checking method according to an embodiment of the present invention can use a hash chain. Hash chain is the initial value (v _n) applied to the hash function (Hash function) to (n is a natural number) repeatedly _{(v i-1 = h (} v i)) by a series of successive hash value obtained ({v ₀ , v ₁ , ..., v _n-1 , v _n }. In the hash chain, the initial value (v _n ) and the last hash value (v ₁ ) are used as a private key and a public key, respectively. The number of hash values excluding the public value (v ₀ ) n) is defined as the length of the hash chain. It is easy to obtain v ₀ , v ₁ , ..., v _i-2 , v _i-1 from v _i in the hash chain, but those who do not know the secret value vn are able to obtain v _{i + 1} , v _{i + 2,.} ..., v _n-1 , v _n is stochastically difficult to obtain. And v _i is the receiver receives the v _{i + k} by performing a hash operation from a single k (k is a natural number of 1 or more n-1 or less) can confirm the legitimacy of vi.

2 is a view for explaining a beacon position determining method according to an embodiment of the present invention. FIG. 3 is another diagram for explaining the beacon position determining method of FIG. 2. FIG.

2 and 3, the beacon position checking method includes a first beacon data providing step S100, a second beacon data receiving step S110, a first deciphering step S120, and a beacon position determining step S130. . ≪ / RTI >

The first beacon data providing step S100 is a step in which the beacon manager 200 sets a chain initial value corresponding to each beacon 100 and provides first beacon data including a chain initial value to the beacon 100 Step.

The beacon manager 200 determines whether or not the beacon manager 200 and the beacon manager 200 have the beacon manager 200 and the beacon manager 200, It can mean the secret value set.

The beacon manager 200 may store initial values for performing a hash chain and information on hash functions repeatedly performed at initial values. This information stored in the beacon manager 200 may be provided to the beacon manager 200 from the beacon management server 300 in advance.

The beacon manager 200 may generate a chain initial value v _n used for authentication of the beacon 100 to correspond to each beacon 100. The chain initial value v _n may be stored in the beacon manager and used to decrypt the first ciphertext to be described later.

The beacon manager 200 corresponds to each beacon 100 and includes identification information (ID) for identifying the beacon 100, authentication information (auth) for confirming whether the beacon 100 is authenticated, the generation time information (date) for the generation time of the hash chain including (v _n ) can be generated.

The generated time information (date) will be described to illustrate the information on the hash chain is generated date, including chains initial value (v _n) of the 365 days of the year.

The beacon manager 200 may provide the beacon 100 with the first beacon data including the identification information ID, the authentication information auth, the generation time information date and the chain initial value v _n have.

Second beacon data reception step (S110) comprises a chain the initial value of the first beacon data (v _n) calculated by using the time information (day) to the first hash value (v _day) of the first ciphertext (Ciphertext) encrypted From the beacon 100, the second beacon data including the second beacon data.

4 is a diagram for explaining the second beacon data receiving step of FIG. 2 in more detail. 5 is a diagram for explaining the first decrypting step of FIG. 2 in more detail. FIG. 6 is another diagram for explaining the beacon position determining method of FIG. 2. FIG.

When 4 with reference to FIG. 6 described in greater detail than the second beacon data reception step (S110), receiving a second beacon data (S110) includes a first hash value (v _day) calculation step (S111) A first ciphertext generation step S112, and a second beacon data reception step S113.

A first hash value (v _day) calculation step (S111) is the beacon 100 is a chain the initial value (v _n) repeatedly applying the hash function a number of times corresponding to the time information (day) with respect to the first hash value (v _day may be calculated.

Here, the time information (day) may be a value obtained through the generation time information (date) included in the first beacon data provided from the beacon manager 200 by the beacon 100. More specifically, time information (day), through the difference between the date value of the current time information, information about the current date from the hash chain is generated date, including chains initial value (v _n) of the generation time information (date) It can be a calculated value. That is, the time information (day) may be information on the elapsed time since the hash chain including the chain initial value (v _n ) is generated.

The beacon 100 may repeatedly apply the hash function to the chain initial value initial value v _n by the number of times corresponding to the time information (day). For example, the beacon 100 can obtain a first hash value (v _day) by the present invention, a hash function is applied repeatedly as long as (365-day) in the chain an initial value (v _n).

In addition, the beacon 100 may additionally generate count information (count). Here, the count information (count) may be information for counting the second beacon data repeatedly generated at a predetermined time interval. More specifically, the beacon 100 may increase the count value accumulated according to the generation period of the second beacon data. At this time, the count value can be cycled according to the generation cycle of the hash chain. For example, the count value may be initialized at a period of 24 hours. The count value may accumulate and increase in size each time the beacon 100 generates the second beacon data. For example, if the beacon 100 generates second beacon data once a minute, the count value may increase from 0 to 1440 for 24 hours. If the generation period of the second beacon data is changed, the range of values that the count value can have correspondingly can also be changed. The information on the count value can be understood as count information (count).

First cipher text (ciphertext) generation step (S112) is the beacon 100 is a first hash value (v _day) of the first hashed value (Vday) comprises may be a first step in which first cipher text (ciphertext) is generated using have.

The beacon 100 encrypts the count information, the first hash value ( _vday ), and the authentication information (auth) included in the first beacon data with a secret key to generate a first ciphertext Can be generated. Here, the first hash value ( _vday ) calculated in the above process may be used as the secret key.

The second beacon data receiving step S113 may be a step in which the beacon manager 200 receives the second beacon data including the first ciphertext from the beacon 100. [

The beacon 100 may generate the second beacon data including the first ciphertext generated in the above process and the identification information ID and other information of the beacon 100. [ Here, the other information (etc) may include various information such as the current time, generation information of the beacon 100, and the like.

Thereafter, the beacon manager 200 may perform a decryption step (S120) for the first ciphertext using the second beacon data received from the beacon 100. [

First ciphertext decryption step (S120) is a beacon manager chain initial value stored in the (200) (v _n) a second hash value calculated with using the time information (day) (v _day2) in a first of the second beacon data And decrypting the ciphertext.

The following steps will be described in more detail with reference to FIGS. 5 and 6. The first ciphertext decryption step (S120) includes loading (S121) information corresponding to the identification information (ID) of the beacon, _vday2 ) calculation step S122, and a first ciphertext decryption step S123.

The step S121 of loading the information corresponding to the identification information (ID) of the beacon includes receiving the second beacon data generated from the beacon 100 and transmitting the beacon 100 included in the second beacon data (ID) of the mobile terminal. The beacon manager 200 can retrieve and load data matched with the beacon 100 among the data stored in the memory of the beacon manager 200 through the identification information ID of the beacon 100. [

A second hash value (v _day) calculation step (S122) may be a step of calculating a second hash value (v _day2) using the chain the initial value (v _n) and time information (day) included in the loading information have.

The beacon manager 200 can extract the chain initial value v _n from the loaded information and obtain the time information (day) from the generation time information (date) included in the loaded information as described above . Beacon manager 200 may calculate a second hash value (v _day2) by applying the hash function a number of times corresponding to the time information (day) with respect to the chain, the initial value (v _n).

The first ciphertext decryption step S123 may be a step in which the beacon manager 200 decrypts the first ciphertext of the second beacon data using the second hash value _vday2 . At this time, the beacon manager 200 can use the second hash value ( _vday2 ) as a cryptographic key for decryption.

Thereafter, the beacon manager 200 may perform a beacon position determination step (S 130) using the decrypted first ciphertext.

The beacon position determination step S130 is a step of determining whether the beacon 100 is located within the communication range 10 of the beacon manager 200 by checking the decrypted first ciphertext of the beacon manager 200 .

In more detail, the beacon position determination step S130 includes the decryption process in which the beacon 100 is included in the decrypted first ciphertext and includes the authentication information (auth) for verifying whether the beacon 100 is authenticated and the decrypted first ciphertext And checking the position of the second beacon through the count information (count) for counting the second beacon data repeatedly generated at a predetermined time interval.

The beacon manager 200 transmits the authentication information auth included in the decrypted first ciphertext and the identification information ID of the beacon included in the information in which the first hash value _vday is loaded and the second hash value ( _vday2 ), and if the count information count matches the cycle of the current time, the second beacon data can be determined to be valid. Accordingly, the beacon manager 200 can determine that the beacon 100 is located within the communication range 10 of the beacon manager 200. [

In the beacon position determination step S130, the authentication information (auth) of the first ciphertext and the count information (count) do not match the information stored in the beacon manager 200, or the second beacon data It may be determined that the beacon 100 is lost.

If the beacon manager 200 determines that the beacon 100 is lost, the beacon manager 200 displays a beacon loss warning through the display of the beacon manager 200, and transmits the lost beacon Lost_beacon to the beacon management server 300 through the beacon management server 300 You can register in the Lost_beacon list. The beacon management server 300 can identify the ID of the beacon 100 received by the lost beacon and add the ID of the lost beacon Lost_beacon to the lost beacon list .

As described above, the beacon position determining method according to an embodiment of the present invention does not need to add any additional devices to the beacon 100 by using a hash chain. Therefore, there is an effect of reducing the cost required in tracking the position of the beacons 100 registered in the beacon manager 200.

Further, in transmitting and receiving beacon data between the beacon manager 200 and the beacon 100, by using the time information (day) and the count information (count), the encryption key can be continuously changed, .

7 is a view for explaining a beacon position determining method according to another embodiment of the present invention. FIG. 8 is another diagram for explaining the beacon position checking method of FIG. 7. FIG.

7 and 8, a beacon position checking method according to another exemplary embodiment of the present invention includes a step (S200) of receiving first lost data from a first beacon manager 201, a step (Step S210), receiving second lost beacon data (step S220), providing second lost beacon data to second beacon manager 202 (step S220), receiving fourth lost beacon data from second beacon manager 202 Step S230 and step S240 of locating the location of the beacon.

Hereinafter, in the description of FIGS. 7 to 10, the description of the same configuration or effect as those of FIGS. 1 to 6 will be omitted.

The first beacon manager 201 receives the first lost data S200 includes a first lost key ciphertext including a first ciphertext encrypted using the chain initial value v _n and the time information day Beacon data may be received by the first beacon manager 201 from the lost beacon 101. [

Here, the beacon 101 is a beacon located in the communication range of the first beacon manager 201 and located outside the communication range of the second beacon manager 202, It may be a registered beacon. The original owner of the beacon 101 may be defined as a second beacon manager 202 and the first beacon manager 201 may be defined as a beacon manager located adjacent to the lost beacon 101. [ That is, the beacon 101 can be understood as a lost beacon out of the communication range of the second beacon manager 202.

Referring to FIG. 9, step (S200) of receiving the first lost data by the first beacon manager 201 will be described in more detail as follows. First beacon manager 201 is the first lost step (S200) for receiving data comprises a first hash value (v _day) calculation step (S201), the first cipher text (ciphertext) generation step (S202), the first lost beacons And a data receiving step (S203).

A first hash value (v _day) calculation step (S201) of the first hashed value being a hash function is applied as many times as the number corresponding to the time information (day) for the chain an initial value (v _n) by the beacon 101 ( v _day may be calculated.

First cipher text (ciphertext) generation step (S202) includes a first hash value by a beacon (101) (v _day) the first hash value (v _day) a first step in which the ciphertext (ciphertext) is created that contains the being used is Lt; / RTI >

The first lost beacon data reception step S203 may be a step in which the first beacon manager 201 receives the first lost beacon data including the first ciphertext from the beacon 101. [ Here, the first lost beacon data is beacon data generated by the lost beacon 101, and may be a configuration corresponding to the first beacon data in the description of FIGS. 1 to 6 above.

The step S210 of receiving the second lost beacon data from the first beacon manager 201 may be the step of confirming the beacon 101 as a lost beacon by the first beacon manager 201. [ In addition, the step S210 of receiving the second lost beacon data from the first beacon manager 201 is the same as that of the first beacon manager 201 except that the identification information BM_guest_ID of the first beacon manager 201, , And receiving the second lost beacon data from the first beacon manager 201 by the beacon management server 300. [

At this time, the first beacon manager 201 determines whether the identification information (ID) of the beacon 101 included in the second lost beacon data is stored in the beacon management server 300 and is included in the lost beacon list Information. The first beacon manager 201 can recognize the beacon as a lost beacon if the identification information (ID) of the beacon 101 of the first lost beacon data is included in the lost beacon list.

Thereafter, the first beacon manager 201 transmits the identification information (ID) of the beacon 101, the first ciphertext generated in the beacon 101, the time at which the lost beacon 101 was retrieved, It may generate the second lost beacon data including information such as the position (GPS) of the beacon 101 and transmit the generated second lost beacon data to the beacon management server 300. [

The step S220 of transmitting the third lost beacon data to the second beacon manager 202 causes the beacon management server 300 to transmit the second lost beacon to the second beacon manager 202 matching the beacon identification information And providing third lost beacon data corresponding to the data.

The beacon management server 300 may search the database to search for the second beacon manager 202 that matches the identification information (ID) of the lost beacon 101. [ Thereafter, the beacon management server 300 generates third lost beacon data including identification information (ID) of the lost beacon 101 and found time information (Found_Time) and provides the third lost beacon data to the second beacon manager 202 . At this time, the found time information (Found_Time) may include information on the date and time when the lost beacon 101 is found by the first beacon manager 201. [

The step (S230) of receiving the fourth lost beacon data from the second beacon manager 202 may be performed when the beacon management server 300 receives the chain initial value v _n stored in the second beacon manager 202 and the time information (day) From the second beacon manager 202, fourth lost beacon data including a second cipher text encrypted using the second cipher text.

Referring to FIG. 10, the step (S230) of receiving the fourth lost beacon data from the second beacon manager 202 will be described in more detail. Receiving a fourth lost beacon data from the second beacon manager (202) (S230) identification information (ID) verification step of the beacon (S231), the second hash values (v _day2) calculation step (S232), the second A ciphertext (Lost_Ciphertext) generation step (S233), and a fourth lost beacon data reception step (S234).

The identification information (ID) confirmation step (S231) of the beacon confirms the identification information (ID) of the beacon 101 from the third lost beacon data received from the beacon management server 300 by the second beacon manager 202 Lt; / RTI >

A second hash value (v _day2) calculation step (S232) is a second beacon manager 202 the chain an initial value which is assigned to the beacon 101, the hash function a number of times corresponding to the time information (day) on (v _n) To calculate the second hash value ( _vday2 ).

To this end, the second beacon manager 202 uses the found time (Found_Time) included in the third lost beacon data received from the beacon management server 300 to calculate the time information (day) and the count information Can be calculated.

The second cipher text (Lost_Ciphertext) generation step (S233) is a second beacon manager 202 and a second hash value (v _day2) the second hash value (v _day2) days to produce a second cipher text with the use .

More specifically, the second beacon manager 202 a second hash value with the secret key a (v _day2) count information (count) and the second hash value (vday2), the authentication information that has been given for the beacon (101) (auth ) To generate a second cipher text (Lost_Ciphertext).

The fourth lost beacon data receiving step S234 receives the second cipher text (Lost_Ciphertext), the second beacon manager's identification information (BM_owner_ID), the beacon identification information (ID) from the second beacon manager 202, And the fourth lost beacon data including the fourth lost beacon data.

In step S240, the beacon management server 300 compares the first ciphertext with the second ciphertext Lost_Ciphertext to inform the second beacon manager 202 of the location of the beacon 101 May be a step.

At this time, the beacon management server 300 decrypts the first ciphertext and the second ciphertext (Lost_Ciphertext), and then transmits the count information (count) included in the first ciphertext and the second ciphertext (Lost_Ciphertext) hash values may be compared to at least one of (v _day, v _day2) and authentication information (auth).

The beacon management server 300 may provide the second beacon manager 202 with identification information (ID) and location information (GPS) of the beacon 101 if the comparison result is valid.

As described above, the present invention can identify the location of a lost beacon even if the beacon is lost out of communication range of the beacon manager, and can provide an improved security function in this process.

That is, after a malicious attacker reports the beacon to another beacon management server 300 as if the malicious beacon is mistaken as being his or her own one, the beacon position of the other beacon is grasped, thereby infringing the privacy of the one beacon user or taking a lost beacon Beaver users can be protected from airspace. This is because a malicious user can not generate a ciphertext for authentication, and therefore authentication with the beacon management server 300 is impossible.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments described in the present invention are not intended to limit the technical spirit of the present invention but to illustrate the present invention. The scope of protection of the present invention should be construed by the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

100: Beacon 200: Beacon manager
300: Beacon management server

Claims (16)

In order for the beacon manager to determine the location of the beacon,
Setting a chain initial value corresponding to each beacon, and providing first beacon data including the chain initial value to a beacon;
Receiving a first beacon value from the beacon, the first beacon data including a first cipher text encrypted with the first hash value, wherein the first hash value is computed using time information to the chain initial value of the first beacon data; ;
Decrypting the first ciphertext of the second beacon data with a second hash value calculated using the chain initial value and the time information stored in the beacon manager; And
Determining whether the location of the beacon is within the communication range of the beacon manager by checking the decrypted first cipher text; / RTI > 2. The method of claim 1, wherein receiving the second beacon data from the beacon comprises:
The first hash value is calculated by repeatedly applying a hash function to the chain initial value by a number corresponding to the time information;
Generating the first ciphertext including the first hash value using the first hash value;
Receiving the second beacon data including the first cipher text from the beacon; Wherein the beacon locator comprises: 2. The method of claim 1, wherein the first beacon data
Further comprising at least one of identification information for identifying the beacon, authentication information for confirming whether the beacon is authenticated, and generation time information for generating the chain initial value. 4. The method of claim 3,
And calculating the beacon position using the generated time information and the current time information. 4. The method of claim 3, wherein the first cipher text is
And the authentication information of the first beacon data is further encrypted. 2. The method of claim 1, wherein the first cipher text is
Further comprising count information for counting the second beacon data repeatedly generated at a predetermined time interval. 2. The method of claim 1, wherein the decoding comprises:
Loading information corresponding to identification information of the beacon included in the received second beacon data;
Calculating the second hash value using the chain initial value included in the loaded information and the time information; And
Decrypting the first ciphertext of the second beacon data using the second hash value; Wherein the beacon locator comprises: 2. The method of claim 1, wherein the determining comprises:
The beacon information included in the decrypted first cipher text and used for authentication of the beacon and the count information for counting the second beacon data included in the decrypted first cipher text and repeatedly generated at a predetermined time interval, The position of the beacon is confirmed. 9. The method of claim 8, wherein the determining comprises:
When the authentication information and the count information of the first ciphertext do not match the information stored in the beacon manager or the second beacon data is not received in a predetermined time unit, A method of locating a beacon. 10. The method of claim 9,
Displaying a beacon loss warning and registering the beacon in a lost beacon list if the beacon is determined to be lost; Further comprising the step of: A method for a beacon management server to determine a location of a beacon,
Receiving first lost beacon data including a first cipher text encrypted using a chain initial value and time information by a first beacon manager;
Receiving from the first beacon manager second beacon data including the identification information of the first beacon manager and the first lost beacon data, the beacon being identified by the first beacon manager as a lost beacon; ;
Providing third lost beacon data corresponding to the second lost beacon data to a second beacon manager that matches the beacon identification information;
Receiving, from the second beacon manager, fourth lost beacon data including a chain initial value stored in the second beacon manager and a second cipher text encrypted using the time information; And
Comparing the first cipher text and the second cipher text to inform the second beacon manager of the location of the beacon; Wherein the beacon locator comprises: 12. The method of claim 11, wherein the first lost beacon data is received by the first beacon manager
A first hash value is calculated by repeatedly applying a hash function to the chain initial value by a number corresponding to the time information;
Generating the first ciphertext including the first hash value using the first hash value; And
Receiving the first lost beacon data including the first cipher text from the beacon by the first beacon manager; Wherein the beacon locator comprises: 12. The method of claim 11, wherein receiving the second lost beacon data from the first beacon manager comprises:
Determining whether the beacon is lost or not based on whether the beacon identification information is included in the lost beacon list in the beacon management server. 12. The method of claim 11, wherein receiving the fourth lost beacon data from the second beacon manager comprises:
The second beacon manager verifying identification information of the beacon from the third lost beacon data;
Calculating a second hash value by repeatedly applying a hash function to the chain initial value assigned to the beacon by the second beacon manager a number of times corresponding to the time information;
Generating the second cipher text including the second hash value using the second hash value; And
Receiving the fourth lost beacon data including the second cipher text from the second beacon manager; Wherein the beacon locator comprises: 12. The method of claim 11, wherein the step of locating the beacon comprises:
And comparing the at least one of the count information, the hash value, and the authentication information included in the first ciphertext and the second ciphertext, after decrypting the first ciphertext and the second ciphertext, . 12. The method of claim 11,
Wherein the beacon is within a communication range of the first beacon manager and is outside a communication range of the second beacon manager.

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