KR20190102575A - Ingestible authentication device and authentication method using the same - Google Patents

Abstract

The present invention relates to a doseable authentication apparatus, and to authentication method using the same. According to an embodiment of the present invention, the authentication apparatus includes an authentication device driving circuit and a contact electrode. The authentication device driving circuit generates authentication data based on the request data. The contact electrode is disposed on the surface of a protective capsule surrounding the authentication device driving circuit. The contact electrode is configured to deliver the request data to the authentication device driving circuit, and to transmit the authentication data. According to the present invention, the external leakage of the authentication device is minimized, and the convenience of personal authentication can be secured.

Description

Takeable authentication device and authentication method using same {INGESTIBLE AUTHENTICATION DEVICE AND AUTHENTICATION METHOD USING THE SAME}

The present invention relates to identity authentication, and more particularly, to an authentication device that can be taken and an authentication method using the same.

In view of safety of users and protection of personal information, there is an increasing demand for an authentication device and an authentication method capable of securing a higher level of security. Such an authentication device and an authentication method may be utilized in various fields such as access to a specific electronic device using an access to a specific place, a login, or a payment system. The authentication device and the authentication method are important not only for securing the security of the data itself through encryption but also for preventing the loss and theft of the authentication device itself.

Conventionally, the user is authenticated using a card or a portable electronic device. Such an authentication device has an advantage that it is easy to carry, but it is vulnerable to loss and theft of the authentication device, and has a disadvantage that cannot be authenticated when it does not operate due to a failure of the authentication device. In addition, when it is difficult to take out the possessed authentication device to the outside, such as a situation where two hands are difficult to use, it may be inconvenient or impossible to perform the authentication operation. In addition, when the user's body such as a fingerprint or iris is used as an authentication method, it may be difficult to authenticate the user due to unclear physical characteristics or body damage. Therefore, there is a demand for an authentication device and an authentication method capable of preventing the loss and theft of the authentication device while ensuring convenience of personal authentication.

The present invention provides a taking authentication device and an authentication method using the same, which minimizes external leakage such as loss and theft, and secures convenience of authentication.

A doseable authentication device according to an embodiment of the present invention includes an authentication device drive circuit and a contact electrode. The authentication device drive circuit generates authentication data based on the request data. The contact electrode may be disposed on the surface of the protective capsule surrounding the authentication device drive circuit. The contact electrode may transmit request data received from the living body to the authentication device driving circuit, and transmit the authentication data to the living body. The contact electrode may be configured to be in contact with the living body. The authentication device may further include a battery embedded in the protective capsule and providing a driving power to the authentication device driving circuit.

The authentication device driving circuit may include a signal receiving circuit, a signal transmitting circuit, and an operation control circuit. The signal receiving circuit can receive the request data from the contact electrode. The signal transmission circuit can transmit authentication data to the contact electrode. The operation control circuit may store the authentication information and output the authentication information to the signal transmission circuit in response to the request data.

The operation control circuit may include a transmission / reception control circuit, an authentication control circuit, an activation control circuit, and a memory. The transmission and reception control circuit may control the signal reception device and the signal transmission device. The authentication control circuit may receive the authentication information from the memory when the request data is detected, and provide the authentication information to the signal transmission circuit. The activation control circuit can control the activation time of the authentication device driving circuit. The activation control circuit may set the activation time based on the activation control data received from the contact electrode.

In the authentication method using the authentication device according to an embodiment of the present invention, the step of transmitting the request data to the authentication device ingested through the living body contacted by the identification device, the authentication device generates authentication data in response to the request data, identification The device receiving authentication data via the biometric, and the identification device performing an authentication operation based on the authentication data. In one example, the authentication method may further comprise setting an activation time of the authentication device before the authentication device is ingested. In one example, the authentication method may further include setting, by the authentication apparatus, an activation time of the authentication apparatus based on the activation control data received through the contact electrode in contact with the living body.

The doseable authentication device and the authentication method using the same according to an embodiment of the present invention are configured to be ingested into the body, thereby minimizing external leakage and ensuring convenience of personal authentication. In addition, the doseable authentication device and the authentication method using the same according to an embodiment of the present invention can be implemented at low power using human body communication and two-way communication, it can be implemented to be advantageous in miniaturization.

1 is a schematic diagram of an authentication system according to an embodiment of the present invention.
FIG. 2 is an exemplary schematic diagram of the authentication device of FIG. 1.
3 is an exemplary block diagram of the authentication device of FIG. 1.
4 is an exemplary block diagram of the authentication device driving circuit of FIG. 3.
5 is a flowchart of an authentication method using an authentication system according to an embodiment of the present invention.
FIG. 6 is a flowchart illustrating steps for authenticating the user of FIG. 5.

In the following, embodiments of the present invention are described clearly and in detail so that those skilled in the art can easily practice the present invention.

1 is a schematic diagram of an authentication system according to an embodiment of the present invention. Referring to FIG. 1, the authentication system 1000 includes an ingestible authentication device 100 (hereinafter, referred to as an authentication device) and an identification device 200. The authentication system 1000 may be applied to various fields for identifying an user USER and performing an authentication operation. For example, the authentication system 1000 may be utilized for access to a specific place such as an entrance of a building, access of a specific electronic device such as login of a computer, or use of a specific system such as a payment system.

The authentication device 100 may be configured to be ingested by the user USER. The authentication device 100 may be encapsulated in a size that can be ingested by the user USER. The authentication device 100 may include a protective capsule and an authentication device driving circuit embedded in the protective capsule. The protective capsule may include a material that protects the authentication device 100 so that the authentication device 100 is not digested. When the authentication device 100 is ingested into the body of the user USER, the authentication device 100 is difficult to leak from another person. That is, the taking authentication device 100 can secure safety from theft and loss. In addition, the authentication apparatus 100 does not need to be carried in a bag or a pocket, and the operation such as approaching the authentication apparatus 100 to a specific area by hand is not required. Since the authentication operation is performed by simply touching a part of the body, the convenience of identity authentication can be secured.

The authentication device 100 may perform biometric communication with the identification device 200 through a user USER. The authentication device 100 may contact a part of the user's body. The authentication device 100 may perform biometric communication with the body of the contacted user USER. To this end, the authentication device 100 may include a contact electrode formed on the surface of the protective capsule. The contact electrode may be configured to be in contact with the user USER. In the case of using the biological communication, the configuration of the RF circuit or antenna for wireless communication is not required for the authentication device 100. In addition, the authentication device 100 does not require power to drive the RF circuit. Therefore, the authentication apparatus 100 using the biological communication may be implemented at a lower power than when using the wireless communication, and may be advantageous in miniaturization.

The authentication device 100 may perform bidirectional communication with the identification device 200. For example, the authentication device 100 may receive request data from the identification device 200 through a user USER. The authentication device 100 may transmit authentication data to the identification device 200 in response to the request data. Since the authentication apparatus 100 generates and transmits authentication data when request data is received, the authentication apparatus 100 may be implemented at a lower power than when transmitting authentication data periodically without receiving additional data. In addition, the authentication device 100 may receive data from the identification device 200 or another external device, and may transmit data to the identification device 200 or another external device.

The identification device 200 may authenticate the user USER using the authentication device 100. The identification device 200 may identify and authenticate the user USER based on the received authentication data. The identification device 200 may be one of various devices requiring an authentication operation. For example, the identification device 200 may be a device that opens a gate to allow an identified and authenticated user USER to access a specific place. Alternatively, the identification device 200 may be a computer device that authorizes access to a specific electronic device or a specific system. The identification device 200 may be a fixed electronic device or may be a portable electronic device such as a smartphone.

The identification device 200 may perform biometric communication with the authentication device 100 through a user USER. The identification device 200 may receive authentication data from the authentication device 100 through a user USER. That is, the identification device 200 may perform biometric communication using a human body as a medium. For example, when the identification device 200 approaches or contacts the user USER, the identification device 200 may transmit request data to the authentication device 100, and in response to the request data, the authentication device 100. ) Can receive the authentication data sent. Alternatively, the identification device 200 may be configured to detect the access or contact of the user USER, and when the access or contact of the user USER is detected, the identification device 200 authenticates from the authentication device 100. Data can be received.

FIG. 2 is an exemplary schematic diagram of the authentication device of FIG. 1. Referring to FIG. 2, the authentication device 100 includes a protective capsule 110, a battery 120, an authentication device driving circuit 130, and a contact electrode 140. The authentication device 100 of FIG. 2 will be understood as an exemplary embodiment of the authentication device 100 of FIG. 1. That is, the authentication device 100 is not limited to the authentication device 100 of FIG. 2, and an authentication device having various shapes, structures, and functions may be provided. For convenience of description, FIG. 2 is described with reference to the reference numerals of FIG. 1.

The protective capsule 110 may surround the battery 120 and the authentication device drive circuit 130. When the authentication device 100 is taken into the body of the user USER, the protective capsule 110 protects the battery 120 and the authentication device driving circuit 130 from chemical damage or physical damage caused by muscles or the like. Can be configured. The protective capsule 110 may include a curved surface such as an ellipse so as not to damage the inner wall of the user USER when the authentication device 100 is ingested. However, the shape of the protective capsule 110 is not limited to the shape of Figure 2 may be formed in various ways.

The battery 120 may provide driving power to the authentication device driving circuit 130. The battery 120 may be, for example, a lithium battery, but is not limited thereto. The battery 120 may be electrically connected to the authentication device driving circuit 130. 2 illustrates that the battery 120 and the authentication device driving circuit 130 are separated, but are not limited thereto. For example, the battery 120 may be disposed on a circuit board on which the authentication device driving circuit 130 is implemented. As described with reference to FIG. 1, when the authentication apparatus 100 performs bidirectional biological communication with the identification apparatus 200, power required for the authentication apparatus 100 may be reduced. In this case, the size of the battery 120 may be reduced, and the capacity of the battery 120 may be reduced. Accordingly, the size of the authentication device 100 can be reduced.

The authentication device driving circuit 130 may perform an operation for generating authentication data. For example, the authentication device driver circuit 130 may receive request data from the identification device 200. To this end, the authentication device driving circuit 130 may be electrically connected to the contact electrode 140. The authentication device driving circuit 130 may generate authentication data in response to the received request data. The authentication device driving circuit 130 may transmit the generated authentication data to the identification device 200 through the contact electrode 140. The authentication device driving circuit 130 may be configured to store authentication information for generating authentication data.

The authentication device driving circuit 130 may control and manage overall operations of the authentication device 100. For example, the authentication device driver circuit 130 may control data communication, such as receiving request data or transmitting authentication data. In addition, the authentication device driving circuit 130 may be implemented to set an activation time, that is, an operating time of the authentication device 100. In addition, the authentication device driving circuit 130 may control various operations for performing an authentication function of the authentication system 1000. The authentication device driving circuit 130 may be implemented as an integrated circuit formed on a substrate, but is not limited thereto. The detailed description of the authentication device driving circuit 130 will be described later.

The contact electrode 140 may be configured to perform biometric communication with the identification device 200 through a user USER. The contact electrode 140 may include a conductive material. For example, the contact electrode 140 may receive request data from the identification device 200 through the user USER, and transmit the request data to the authentication device driving circuit 130. The contact electrode 140 may receive authentication data from the authentication device driving circuit 130 and transmit the authentication data to the identification device 200 through the user USER. In addition, the contact electrode 140 may transfer various data between the authentication device 100 and the identification device 200.

The contact electrode 140 may be configured to contact the user USER in the body of the user USER. The contact electrode 140 may be exposed to the outside to be in contact with the user USER. 2 illustrates that the contact electrode 140 is disposed on a part of the surface of the protective capsule 110, but is not limited thereto. The contact electrode 140 may be patterned in various shapes and configurations. For example, the contact electrode 140 may form part of the protective capsule 110. Alternatively, the contact electrode 140 may be formed in the protective capsule 110 to be adjacent to the user USER at a minute interval. Alternatively, a protection layer (not shown) disposed on the contact electrode 140 may be further included in the authentication device 100 to protect the contact electrode 140 from body fluids or the like.

3 is an exemplary block diagram of the authentication device of FIG. 1. Referring to FIG. 3, the authentication device 100 includes a battery 120, an authentication device driving circuit 130, and a contact electrode 140. Each of the battery 120, the authentication device driving circuit 130, and the contact electrode 140 has substantially the same configuration and function as the battery 120, the authentication device driving circuit 130, and the contact electrode 140 of FIG. 2. Can have However, the authentication device 100 of FIG. 3 will be understood as an exemplary embodiment of the authentication device 100 of FIG. 1 or 2, and the configuration of the authentication device 100 is not limited to FIG. 3. For convenience of description, FIG. 3 is described with reference to the reference numerals of FIGS. 1 and 2.

The authentication device driving circuit 130 includes a signal transmission circuit 131, a signal receiving circuit 132, and an operation control circuit 133. The authentication device driving circuit 130 may be driven based on the driving power provided from the battery 120. The signal transmission circuit 131 and the signal receiving circuit 132 may be configured to perform bidirectional biocommunication with the identification device 200 under the control of the operation control circuit 133. To this end, the signal transmission circuit 131 transmits authentication data to the user USER through the contact electrode 140, and the signal receiving circuit 132 receives request data from the user USER through the contact electrode 140. Can be received.

The signal transmission circuit 131 may generate authentication data and transmit the authentication data to the contact electrode 140. The signal transmission circuit 131 may receive authentication information from the operation control circuit 133. The authentication information includes information for identifying the user USER, such as a code specific to the user USER. The signal transmission circuit 131 may generate authentication data based on the authentication information. The authentication data may be a digital signal, but is not limited thereto. The signal transmission circuit 131 may generate authentication data according to a protocol required by the authentication system 1000 and output the authentication data to the contact electrode 140. For example, the signal transmission circuit 131 may include a signal converter or a signal amplifier for converting authentication information into authentication data. This signal converter or signal amplifier can be operated under the control of the operation control circuit 133. Since the signal transmission circuit 131 performs data communication in a biological communication method, a separate RF circuit for wireless communication or the like may not be required.

The signal receiving circuit 132 may receive request data from the contact electrode 140 and output the request data to the operation control circuit 133. The request data may be a digital signal, but is not limited thereto. The signal receiving circuit 132 may receive data according to a protocol required by the authentication system 1000. The signal receiving circuit 132 may restore the request data to the data transmitted from the identification device 200 and output the request data to the operation control circuit 133. For example, the signal receiving circuit 132 may include a data recovery circuit to restore the request data to the same data and clock as the digital signal output from the identification device 200. This data recovery circuit may be operated under the control of the operation control circuit 133. Since the signal receiving circuit 132 performs data communication in a biological communication method, a separate RF circuit for wireless communication or the like may not be required.

The operation control circuit 133 may output authentication information to the signal transmission circuit 131 in response to the request data received from the signal receiving circuit 132. The operation control circuit 133 manages authentication information for generating authentication data. The authentication information may be stored in the operation control circuit 133, and the operation control circuit 133 may read the stored authentication information according to the received request data and output the read authentication information to the signal transmission circuit 131. However, the present invention is not limited thereto, and the operation control circuit 133 periodically transmits the authentication information to the signal transmission circuit 131, thereby causing the authentication device 100 to periodically transmit the authentication data. You can also control it.

In addition, the operation control circuit 133 may perform an operation for performing various functions including an authentication function of the authentication apparatus 100. For example, the authentication device 100 may perform data communication with another external device in addition to the identification device. The operation control circuit 133 may receive external control data received from another external device through the contact electrode 140 and the signal receiving circuit 132. The operation control circuit 133 may control the authentication apparatus 100 based on external control data. For example, the operation control circuit 133 may set an activation time of the authentication device driving circuit 130 or block an operation of the authentication device driving circuit 130 based on external control data. Alternatively, the operation control circuit 133 may select or change the authentication information to be output based on the external control data, or select or change the format of the authentication data to be generated.

4 is an exemplary block diagram of the authentication device driving circuit of FIG. 3. Referring to FIG. 4, the authentication device driving circuit 230 includes a signal transmitting circuit 231, a signal receiving circuit 232, and an operation control circuit 233. Each of the signal transmission circuit 231, the signal reception circuit 232, and the operation control circuit 233 is substantially the same as the signal transmission circuit 131, the signal reception circuit 132, and the operation control circuit 133 of FIG. 3. It may have the same configuration and function. However, the authentication device driving circuit 230 of FIG. 4 will be understood as an exemplary embodiment of the authentication device driving circuit 130 of FIG. 3, and the configuration of the authentication device driving circuit 130 is not limited thereto. For convenience of description, FIG. 4 is described with reference to the reference numerals of FIG. 3.

The signal transmission circuit 231 outputs the authentication data ID to the contact electrode 140 of FIG. 3 to perform an authentication operation. The signal transmission circuit 231 may generate authentication data ID. The signal transmission circuit 231 may receive authentication information from the operation control circuit 233 to generate authentication data ID.

The signal receiving circuit 232 receives the request data Req for the signal transmitting circuit 231 to transmit the authentication data ID from the contact electrode 140 of FIG. 3. The signal receiving circuit 232 may output the restored request data to the operation control circuit 233 by restoring the received request data Req to be the same as the data output by the identification device.

The operation control circuit 233 may include a transmission / reception control circuit 234, an authentication control circuit 235, an activation control circuit 236, and a memory 237. The transmission / reception control circuit 234 may control operations of the signal transmission circuit 231 and the signal reception circuit 232. The transmission / reception control circuit 234 may generate a control signal for controlling the signal transmission circuit 231 and the signal reception circuit 232. The signal transmission circuit 231 may convert authentication information into authentication data ID based on a control signal generated by the transmission and reception control circuit 234, and output the authentication data ID to the contact electrode 140. have. The signal receiving circuit 232 may restore the request data Req based on the control signal generated by the transmission / reception control circuit 234, and may output the restored request data Req to the operation control circuit 233.

The authentication control circuit 235 may manage the authentication information to generate the authentication data ID in response to the request data Req. The authentication control circuit 235 may receive the request data restored from the signal receiving circuit 232. The authentication control circuit 235 may detect that the restored request data is received. When the reception of the request data Req is detected, the authentication control circuit 235 may read authentication information stored in the memory 237. The authentication control circuit 235 may select authentication information to be read out according to the type of request data Req. The authentication control circuit 235 may provide the read authentication information to the signal transmission circuit 231.

The activation control circuit 236 can determine the operation time or whether the authentication device driving circuit 230 operates. The operating time of the authentication device driving circuit 230 may be set in advance before the user takes the authentication device. For example, the activation control circuit 236 may set the operation time to the time until the authentication device is discharged out of the body through a digestive organ or the like. Activation control data for setting the operation time before the user takes the authentication device may be provided to the activation control circuit 236 via the signal receiving circuit 232, and the activation control circuit 236 is based on the activation control data. The operating time of the authentication device driving circuit 230 can be set. However, the present invention is not limited thereto, and after the user takes the authentication device, the activation control circuit 236 may receive activation control data from an external device through the signal receiving circuit 232. The activation control circuit 236 may include a counter for counting the set operating time.

The activation control circuit 236 may block the operation of the authentication device driving circuit 230 when the set operating time has passed. For example, the activation control circuit 236 may block the power supply of the authentication device driving circuit 230 from the battery when the set operating time has passed. Alternatively, the activation control circuit 236 may initialize the authentication device driving circuit 230 so that the authentication device cannot be reused when the set operation time has passed. By setting the operation time, it is possible to prevent the authentication apparatus from being reused and to prevent the authentication information of the user from being exposed to other people.

The memory 237 may be configured to store authentication information for the user. Authentication information for the user may be stored in advance in the memory 237 before the user takes the authentication device. However, the present invention is not limited thereto, and after the user takes the authentication device, authentication information provided from an external device through the signal receiving circuit 232 may be stored in the memory 237. In response to the request data Req, authentication information stored in the memory 237 may be provided to the authentication control circuit 235. A plurality of pieces of authentication information may be stored in the memory 237. In this case, selected pieces of pieces of authentication information may be provided to the authentication control circuit 235 according to the type of request data Req. The authentication information may be deleted from the memory 237 when the operation time set by the activation control circuit 236 has passed. The memory 237 may include a nonvolatile memory device or a volatile memory device.

5 is a flowchart of an authentication method using an authentication system according to an embodiment of the present invention. Referring to FIG. 5, the authentication method is performed in the authentication system 1000 of FIG. 1. For convenience of description, FIG. 5 is described with reference to FIGS. 1 and 3.

In step S110, the activation time, that is, the operating time of the authentication device 100 is set. The activation time may be set in consideration of the time point at which the authentication device 100 is discharged from the user USER from the time when the authentication device 100 is ingested by the user USER. Alternatively, the activation time may be set in consideration of the time at which the authentication authority is determined to be granted. The authentication device 100 may set an activation time using the authentication device driving circuit 130 and count the set activation time. Unlike in FIG. 5, the activation time may be set after ingesting the authentication device 100. In this case, the authentication device 100 may receive activation control data from an external device through the contact electrode 140, and an activation time may be set based on the activation control data.

In operation S120, the user USER ingests the authentication device 100. The ingested authentication device 100 may contact the inner wall of the user USER. The authentication device 100 may perform biometric communication with the contacted user USER. In operation S130, the user USER may contact the identification device 200. When the user USER is in contact with the identification device 200, the authentication device 100 and the identification device 200 may perform biometric communication using the user USER as a medium.

In operation S140, the authentication system 1000 authenticates a user USER. For example, the identification device 200 may transmit request data to the contacted user USER, and the authentication device 100 may receive request data through the user USER. The authentication device 100 may receive request data through the contact electrode 140, and the authentication device driving circuit 130 may transmit authentication data to the contact electrode 140 in response to the request data. The identification device 200 may identify and authenticate the user USER based on the authentication data through the user USER. The identification device 200 may perform an operation such as granting an access right to the user USER based on the authentication data.

In step S150, the authentication device 100 is discharged from the user (USER) through the digestive organs. In this case, the operation of the authentication device driving circuit 130 may be blocked based on the activation time set in step S110. Therefore, the authentication apparatus 100 discharged outside the body may not be reused, and authentication information may not be leaked to the outside.

FIG. 6 is a flowchart illustrating a step S140 of authenticating a user of FIG. 5. Referring to FIG. 6, step S140 of authenticating a user is performed by the authentication system 1000 of FIG. 1. For convenience of description, FIG. 6 is described with reference to FIGS. 1 and 3.

In operation S141, the authentication apparatus 100 may determine whether to receive request data. When the user USER is in contact with the identification device 200, the identification device 200 may transmit request data to the authentication device 100 through the user USER. The request data may be a digital signal. The authentication device driving circuit 130 included in the authentication device 100 may detect request data received by the signal receiving circuit 132. If the request data is received, step S142 is performed. If the request data is not received, the authentication device 100 may determine again whether the request data has been received.

In operation S142, the authentication apparatus 100 generates authentication data. The authentication device driving circuit 130 may receive authentication information stored in a memory when the request data is detected. The operation control circuit 133 may output authentication information to the signal transmission circuit 131. The signal transmission circuit 131 may generate authentication data based on the authentication information. The authentication data may be a digital signal. The signal transmission circuit 131 may transmit authentication data to the contact electrode 140.

In operation S143, the identification device 200 receives authentication data. The authentication data may be provided to the identification device 200 through the user USER. The identification device 200 may include a signal receiving circuit for receiving authentication data. The signal receiving circuit may include a restoration circuit for restoring the authentication data to be the same as the data transmitted by the authentication apparatus 100. The identification device 200 may identify and authenticate the user USER based on the restored authentication data.

Steps S141 to S143 shown in FIG. 6 may be repeated to identify and authenticate the user USER. For example, depending on the protocol required for authentication in the authentication system 1000, steps S141 to S143 may be repeated several times, and the identification device 200 may identify and authenticate the user USER according to the repetition. Can be.

The above description is specific examples for practicing the present invention. The present invention will include not only the embodiments described above but also embodiments that can be easily changed or simply changed in design. In addition, the present invention will also include techniques that can be easily modified and carried out using the above-described embodiments.

1000: authentication system 100: authentication device
110: protective capsule 120: battery
130, 230: authentication device drive circuit 131, 231: signal transmission circuit
132, 232: signal receiving circuit 133, 233: operation control circuit
140: contact electrode 200: identification device

Claims (15)

In the authentication device which can be taken,
An authentication device driving circuit that generates authentication data based on the request data; And
And a contact electrode disposed on a surface of a protective capsule surrounding the authentication device driving circuit, the contact electrode transmitting the request data to the authentication device driving circuit, and transmitting the authentication data. According to claim 1,
And the request data is received through the contact electrode in contact with a living body, and the authentication data is transmitted in response to the request data. According to claim 1,
The authentication device drive circuit,
A signal receiving circuit for receiving the request data from the contact electrode; And
And a signal transmission circuit for transmitting the authentication data to the contact electrode. The method of claim 3, wherein
The authentication device drive circuit,
And an operation control circuit for storing authentication information and outputting the authentication information to the signal transmission circuit in response to the request data. The method of claim 4, wherein
The operation control circuit,
And a transmission / reception control circuit for controlling the signal reception device to receive the request data and controlling the signal transmission device to transmit the authentication data based on the authentication information. The method of claim 4, wherein
The operation control circuit,
A memory in which the authentication information is stored; And
And an authentication control circuit for providing the authentication information to the signal transmission circuit when the request data is detected. The method of claim 4, wherein
The operation control circuit,
And an activation control circuit for controlling an activation time of the authentication device driving circuit. The method of claim 7, wherein
The activation control circuit,
And set the activation time based on the activation control data received from the contact electrode. According to claim 1,
And a battery embedded in the protective capsule, the battery providing driving power to the authentication device driving circuit. Transmitting, by the identification device, request data to the authentication device ingested through the contacted living body;
Generating, by the authentication apparatus, authentication data in response to the request data;
Receiving, by the identification device, the authentication data through the living body; And
And the identification device performing an authentication operation based on the authentication data. The method of claim 10,
Generating the authentication data,
Receiving, by the authentication device, the request data through a contact electrode in contact with the living body;
And the authentication device converts the stored authentication information into the authentication data in response to the request data. The method of claim 10,
Receiving the authentication data,
And transmitting, by the authentication apparatus, the authentication data to the living body through the contact electrode in contact with the living body. The method of claim 10,
And setting an activation time of the authentication device before the authentication device is ingested. The method of claim 10,
And setting, by the authentication device, an activation time of the authentication device based on activation control data received through the contact electrode in contact with the living body. The method of claim 10,
The step of transmitting the request data,
Detecting, by the identification device, a contact between the living body and the identification device; And
And the identification device sending the request data to the biometric in response to the sensed contact.

Images